Lactobacillus supplement for alleviating type 1 diabetes

ABSTRACT

Isolated  Lactobacillus  strains are useful in preventing or delaying the development of Type 1 Diabetes (T1D). A probiotic composition comprising the  Lactobacillus  strains and use of the composition in T1D prevention are provided.

CROSS-REFERENCE TO A RELATED APPLICATION

This application is a continuation application of U.S. application Ser. No. 13/144,028, filed Oct. 4, 2011, which is a national phase application of International Application No. PCT/US2010/024575, filed Feb. 18, 2010, which claims the benefit of U.S. provisional application Ser. No. 61/153,516, filed Feb. 18, 2009 and U.S. provisional application Ser. No. 61/297,480, filed Jan. 22, 2010, all of which are incorporated herein by reference in their entirety.

The Sequence Listing for this application is labeled “April12012-ST25.txt”, which was created on Apr. 2, 2012, and is 16 KB. The entire content is incorporated herein by reference in its entirety.

BACKGROUND OF INVENTION

Diabetes mellitus is a family of disorders characterized by chronic hyperglycemia and the development of long-term vascular complications. This family of disorders includes type 1 diabetes, type 2 diabetes, gestational diabetes, and other types of diabetes.

Immune-mediated (type 1) diabetes (or insulin dependent diabetes mellitus, IDDM) is a disease of children and adults for which there currently is no adequate means for prevention or cure. Type 1 diabetes, represents approximately 10% of all human diabetes. The disease is characterized by an initial leukocyte infiltration into the pancreas that eventually leads to inflammatory lesions within islets, a process called “insulitis”.

Type 1 diabetes is distinct from non-insulin dependent diabetes (NIDDM) in that only the type 1 form involves specific destruction of the insulin producing beta cells of the islets of Langerhans. The destruction of beta cells appears to be a result of specific autoimmune attack, in which the patient's own immune system recognizes and destroys the beta cells, but not the surrounding alpha cells (glucagon producing) or delta cells (somatostatin producing) that comprise the pancreatic islet. The progressive loss of pancreatic beta cells results in insufficient insulin production and, thus, impaired glucose metabolism with attendant complications.

The factors responsible for type 1 diabetes are complex and thought to involve a combination of genetic, environmental, and immunologic influences that contribute to the inability to provide adequate insulin secretion to regulate glycemia.

The natural history of type 1 diabetes prior to clinical presentation has been extensively studied in search of clues to the etiology and pathogenesis of beta cell destruction. The prediabetic period may span only a few months (e.g., in very young children) to years (e.g., older children and adults). The earliest evidence of beta cell autoimmunity is the appearance of various islet autoantibodies. Metabolically, the first signs of abnormality can be observed through intravenous glucose tolerance testing (IVGTT). Later in the natural history of the disease, the oral glucose tolerance test (OGTT) typically becomes abnormal. With continued beta cell destruction and frank insulinopenia, type 1 diabetes becomes manifest.

Type 1 diabetes occurs predominantly in genetically predisposed persons. Concordance for type 1 diabetes in identical twins is 30-50% with an even higher rate of concordance for beta cell autoimmunity, as evidenced by the presence of islet autoantibodies in these individuals (Pyke, D. A., 1979. “Diabetes: the genetic connections.” Diabetologia 17: 333-343). While these data support a major genetic component in the etiopathogenesis of type 1 diabetes, environmental or non-germline genetic factors must also play important pathologic roles. Environmental factors proposed to date include viral infections, diet (e.g., nitrosamines in smoked meat, infant cereal exposure), childhood vaccines, lack of breast-feeding, early exposure to cows' milk, and aberrant intestinal functioning (Vaarala et al. 2008). Hence, while the list of potential environmental agents for type 1 diabetes is large, the specific environmental trigger(s) that precipitate beta cell autoimmunity remain elusive.

Type 1 diabetes is currently managed by the administration of exogenous human recombinant insulin. Although insulin administration is effective in achieving some level of euglycemia in most patients, it does not prevent the long-term complications of the disease including ketosis and damage to small blood vessels, which may affect eyesight, kidney function, blood pressure and can cause circulatory system complications.

Although knowledge of the immune system has become much more extensive in recent years, the precise etiology of type 1 diabetes remains a mystery. Furthermore, despite the enormously deleterious health and economic consequences, and the extensive research effort, there currently is no effective means for controlling the formation of this disease.

As noted above, one of the numerous factors that has been considered in the context of unraveling the complex etiology of type 1 diabetes is intestinal functioning, including the interaction of intestinal microflora. The presence of a commensal intestinal microbiota in infancy is critical and well documented for numerous physiologic processes including growth, angiogenesis, optimization of nutrition, and stimulation of various arms of the innate and adaptive immune systems. However, similar studies in T1D are limited. In rodent models of T1D, the disease is likely to develop under germ free conditions. Diabetes prone rats (BB-DP) subjected to cesarean derivation develop accelerated disease (Like et al. 1991). In terms of using such information to proactively modulate diabetes formation, the antibiotic treatments to BB-DP rats after weaning (Brugman et al. 2006) prevents diabetes, whereas with the NOD mouse, a decreased frequency of T1D was observed with the administration of doxycycline (Schwartz et al. 2007). Probiotic treatment of non-obese diabetic mice (NOD) prevents the onset of T1D (Calcinaro et al. 2005; Yadav et al. 2007). Similarly, a low fat diet with Lactobacillus strains reduced insulin-dependent diabetes in rats (Matsuzuki et al. 2007). Antibiotics can prevent T1D in diabetes-prone rats (BB-DP) (Brugman et al. 2006) and in NOD mice (Schwartz et al. 2006). The incidence of diabetes in NOD mice increases in a germ-free environment (Suzuki et al. 1987; Wicker et al. 1987). Freund's adjuvant, which contains mycobacteria, also protects NOD mice and the BB-DP rat against diabetes (Sadelain et al. 1990a,b; McInerney et al. 1991). The specific mechanisms of how such therapies modulate disease are unclear.

BRIEF SUMMARY

The subject invention provides compositions for alleviating type 1 diabetes (T1D). In preferred embodiments, the compositions comprise an effective amount of one or more Lactobacillus isolates. Preferably, the bacteria used as an active ingredient in the compositions of the subject invention are a Lactobacillus reuteri strain, a Lactobacillus johnsonii strain, or a combination thereof.

The subject invention also provides methods for preventing or slowing the development of T1D. These methods comprise the administration of a composition of the subject invention, wherein the composition preferably comprises an effective amount of one or more Lactobacillus isolates.

BRIEF DESCRIPTION OF THE SEQUENCES

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BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 shows a gel-like image generated by a bioanalyzer. The first and last columns are the reference DNA 7500 ladder. Base pair sizes are indicated adjacent to the ladder. Samples 1 to 3 represent the ARISA profiles for the intestinal tract of diabetes prone (BB-DP) and samples 4 to 6 represent diabetes resistant (BB-DR) rats' stool samples at 60 days of age. The lower most (50 bp) and the upper most (10380 bp) bands represent the markers used to align the ladder data with data from the sample wells. The boxes represent dominant bands unique to both group and were extracted from the gel for further sequencing. The stool samples used in the ARISA analysis come from experiment 1.

FIGS. 2A1-2A2 and 2B1-2B2 show the principal coordinates analysis (PCA) depicting the qualitative (presence/absence) and quantitative (presence/absence and abundance) of the bacterial communities for the 10 stool samples each from the diabetes-resistant and diabetes-prone rats. This analysis is based on the community structures derived from experiment 1's Sanger sequencing (2A1-A2) and experiment 2's pyrosequencing (2B1-B2).

FIG. 3 shows the Shannon Weaver and richness diversity indices calculated for the three time points after birth when stool was collected. Circles and squares represent the BB-DP and BB-DR samples, respectively. Closed symbols represent the richness index (d) while open symbols depict the Shannon-Weaver (H′) indices. Indices were calculated using ARISA data from the experiment 2 samples.

FIGS. 4A-4B show log of the number of Lactobacillus and Bifidobacterium cells per 5 ng of DNA from diabetes-resistant (BB-DR) and diabetes-prone (BB-DP) stool samples. 4A—experiment 1 (3 stool samples per genotype). 4B—experiment 2 (10 stool samples per genotype). The standard error about the mean is depicted in the error bar about the data columns.

FIG. 5 shows the family-level phylogenetic classification of those OTUs that could not be classified at the genus or species levels. Red branches depict 16S rRNA sequences from BB-DP rats and green branches depict sequences from BB-DR. Branches in black depict known sequences from bacterial isolates. A list of bacterial isolates that were aligned with the sequences obtained from this study can be seen in the supplementary material. Sequences were aligned by using NAST (DeSantis et al., 2006). The aligned sequences and their respective nearest-isolates were uploaded in MEGA 4 (Tamura et al., 2007) for conduction of the phylogenetic analysis. The evolutionary history was inferred using the neighbor-Joining method and the evolutionary distances were computed using the Maximum Composite Likelihood method. All positions containing gaps and missing data were eliminated from the dataset (Complete deletion option). Striking taxonomic trends were observed with the Clostridiaceae and Ruminococcaceae more prevalent in BB-DP while the Lachnospiraceae, Porphyromonadaceae, and Prevotellaceae were more common in BB-DR.

FIG. 6 shows percentage of BioBreeding diabetes-prone (Biomedical Research Models, Worcester, Mass.; BB-DP; N=5 per group) rats that exhibited bacterial translocation to the spleen and pancreas on Blood BHI plates. BB-DP pups were administered with L. johnsonii N6.2 or L. reuteri TD1 at 10⁶ or 10⁸ CFU/animal. Same results were observed on MRS agar.

FIG. 7 shows the feeding design using BB-DP animals. Bacterial strains were administered to BB-DP rats to test whether they would delay or inhibit the onset of type 1 diabetes. L. reuteri TD1 or L. johnsonii N6.2 suspensions (10⁸ CFU) were administered daily by oral gavage. All experiments were conducted with Institutional Animal Care and adherence to prescribed IACUC protocol. Starting on Day 60, the blood glucose levels of animals were taken weekly using a glucose monitor (Accu-chek, Roche Diagnostics). If glucose levels surpassed 250 mg/dl for two consecutive days, the rat was considered diabetic. Immediately after disease development the rat was sacrificed. Organs and tissues were harvested and preserved for analysis as described in Neu et al. (2005), which is hereby incorporated by reference in its entirety. Arrow in black indicates the time that feeding was started. The dashed line indicates daily feeding. The dashed box indicates the period in which rats developed diabetes.

FIGS. 8A-8B show Kaplan-Meier plot depicting the survival of BB-DP rats feed 8A) pre-weaning or 8B) post-weaning with L. johnsonii N6.2 (short dashed line), or L. reuteri TD1 (long dashed line) compared to the PBS feed control (solid line) (N=10 per group).

FIGS. 9A-9B show quantification using real time qPCR of lactobacilli (9A) and enterobacteria (9B) from Ileal mucosa. The values are expressed as mean of the percentages from total bacteria determined from 5 ng of DNA. * indicates significant differences (P<0.05) between healthy and diabetic animals (N=6 per group).

FIGS. 10A-10C show effect of the post weaning administration of L. johnsonii on the intestinal morphology (10A, 10B) and on mRNA levels of tight junction genes (10C). Hematoxylin and eosin stained slides of distal small intestine were examined for morphological changes. (10A) shows measurements of crypt depth, villus height and villus width in L. johnsonii fed group (black bars), healthy control (dark grey bars) and diabetic group (light grey bars). (10B) shows percentage of goblet cells in the distal small intestine in the different treatment groups. (10C) shows RT-qPCR analysis of the expression of tight junction genes. Relative amounts of claudin-1 and occludin were calculated by subtracting the internal control (β actin) and changes in expression levels were calculated relative to its value in the L. johnsonii fed group (expression=1). Grey bars: Relative expression in the healthy control; Black bars: relative expression in the diabetic animals. The values are means+S.D. (N=10); * P<0.05; **P<0.0001; #P<0.01.

FIGS. 11A-11B show assessment of the oxidative stress response in the host. (11A) shows RT-qPCR analysis of the expression of genes linked to the oxidative stress response in the host. Relative amounts of iNOS, Cox2, Sod1, Sod2, Gpx1, Cat, and GR were calculated by subtracting the internal control (β actin), and changes in expression levels were calculated relative to the value in L. johnsonii-fed group (expression=1). Grey bars: relative expression in the healthy control; Black bars: relative expression in the diabetic animals. The values are means+S.D. (N=6); *P<0.05; ^(o)P<0.01, **P<0.0001. (11B) shows western blot analysis of iNOS levels. β actin was used as internal control.

FIG. 12 shows mRNA levels of the pro-inflammatory cytokine genes, IFNγ and TNFα linked to the oxidative stress response in the host. Relative expression was calculated as previously described relative to the value in the L. johnsonii-fed group (expression=1). Relative expression in the L. johnsonii-fed group (black bars); healthy control (dark grey bars) and diabetic animals (light grey bars). The values are means+S.D. (N=6); *P<0.05; #P=0.01.

FIG. 13 shows mRNA levels of IDO ileac mucosa. Relative expression was calculated based on mRNA levels of each group relative to the mRNA level in the L. johnsonii fed group (expression=1). The values are means+S.D. (N=6); *P<0.05.

DETAILED DISCLOSURE

In accordance with the subject invention, it has been found that Lactobacillus strains can be used to alleviate (delay the onset of, and/or reduce the severity or progression of), type 1 diabetes (T1D). In specific embodiments of the subject invention, the administration of Lactobacillus strains such as L. johnsonii can prevent or delay the onset of, or reduce the progression of, T1D.

In one embodiment, the subject invention provides isolated Lactobacillus strains that are able to delay and/or prevent the development of T1D. The preferred strains include Lactobacillus reuteri and Lactobacillus johnsonii. In one embodiment the bacteria is L. johnsonii. Specially exemplified herein is Lactobacillus johnsoni N6.2.

In accordance with the subject invention, it has been found that the oral transfer of Lactobacillus johnsonii N6.2 from DR rodents to DP rodents conferred T1D resistance to DP rodents. Diabetes resistance in Lactobacillus johnsonii N6.2 fed DP rodents was correlated to a TH17 bias within the mesenteric lymph nodes which was associated with high levels of IL6 and IL23. Moreover, in vitro assays showed that Lactobacillus johnsonii N6.2 mediated high IL6 levels in antigen presenting cells which can mediate TH17 differentiation in the presence of sufficient TCR stimulation.

A thorough, culture-independent examination of the diversity of bacteria in the stool of diabetes-prone (DP) and diabetes-resistant (DR) rats just prior to the onset of diabetes was done by a variety of culture-independent approaches. The results of all approaches were in agreement that certain bacterial species are more common in diabetes-resistant than in diabetes-prone rats. The results were verified with two genera using quantitative PCR.

In these 16S rRNA libraries, close relatives of 74 genera were identified. Of those, 18 genera showed higher abundance in one rat genotype versus the other. Of the 9 genera with higher abundance in BB-DR, three genera, Bifidobacterium, Lactobacillus, and Pseudobutyrivibrio, have representatives with known probiotic activity. These observations from pyrosequencing were verified by qPCR of Bifidobacterium and Lactobacillus. These results also confirmed the BB-DR specific ARISA band identified in Example 1 as Lactobacillus. These bacteria may prevent the growth of other strains that cause a leaky gut epithelium and/or cause an altered immune response against gut microbiota.

Of the 9 genera in higher abundance in BB-DP, none are known to have probiotic activity. As expected in stool samples, there are many genera that are strict anaerobes and these genera are found in BB-DR and BB-DP samples. A halophilic genus, Pontibacillus, is found in much higher numbers in BB-DP samples. These observations are consistent with previous work where feeding probiotics or antibiotics to either NOD mice or BB-DP rats prevented diabetes (Brugman et al. 2006; Calcinaro et al. 2005; Matsuzuki et al. 2007; Yadav et al. 2007).

However, species-level differences reveal changes not seen at the genus level. Perhaps the most dramatic example of this is Clostridium. At the genus level, Clostridium abundance does not differ between BB-DR and BB-DP. However, five species of Clostridium are higher in BB-DP than in BB-DR. Only one Clostridium species, C. hylemonae, is higher in BB-DR than in BB-DP. However, of the six species, C. hylemonae appears to be by far the least abundant of these six species. Twenty-one other species of Clostridium were identified in these samples but they did not differ between the two genotypes (Table 1).

Several exogenous as well as endogenous factors could affect the intestinal microbiota in these rats. The environment of these animals including food intake was the same in both BB-DP and BB-DR rats, thus minimizing its contributions to the differences in intestinal microbiota observed between the two strains. Factors other than the environment and genetic background have been shown to contribute to gut microbiota composition.

However, in the work that led to the subject invention, these external factors have been minimized. All rats were provided the same lighting, temperature, diet, water, and cage conditions. BB-DR and BB-DP were in separate cages with two or three rats per cage after weaning from the mother.

A striking feature of this work is the large number of Operational Taxonomy Units (OTUs) that differed between BB-DP and BB-DR but could not be classified to a known genus. At the family level, there were striking taxonomic trends with the Clostridiaceae and Ruminococcaceae more prevalent in BB-DP while the Lachnospiraceae, Porphyromonadaceae, and Prevotellaceae were more common in BB-DR. This suggests a selectivity in the changes that occur in the BB-DP gut over time. Certain taxa appear to be targeted for loss over time in BB-DP. These may be under attack from the immune system or the conditions in the BB-DP gut may be less conducive to their growth.

One embodiment of the subject invention provides a probiotic composition for preventing and/or delaying the onset of T1D (or reducing the severity of T1D) comprising an effective amount of one or more Lactobacillus isolates. The composition can also include pharmaceutically acceptable carriers, additives, or excipients. In one embodiment, the composition includes one or more other probiotic materials.

The amount of the therapeutic or pharmaceutical composition of the invention that is effective in the prevention and/or treatment of T1D can be determined by a person skilled in the art having the benefit of the current disclosure through standard clinical techniques. Relevant factors include, but are not limited to, the type(s) of Lactobacillus strain, the particular physiological symptom or condition, the severity of the disease or condition including the presence or absence of the translocation of normal flora and/or its metabolites, and the degree of the translocation of normal flora and/or its metabolites. The precise dose to be employed in the formulation will also depend on the route of administration, and should be decided according to the judgment of the practitioner and each patient's circumstances. In one embodiment, effective doses can be extrapolated from dose-response curves derived from in vitro or animal model test systems.

In certain embodiments, the subject composition is administered to a subject at a dosage ranging from 10² to 10¹¹ Lactobacillus per day. In a specific embodiment, the subject composition comprises about 10² to 10⁵ L. reuteri as an active ingredient. In another specific embodiment, the subject composition comprises about 10² to 10⁵ L. johnsonii as an active ingredient.

The Lactobacillus strains of the subject invention can be formulated according to known methods for preparing pharmaceutically useful compositions. Formulations are described in a number of sources, which are well known and readily available to those skilled in the art. For example, Remington's Pharmaceutical Science (Martin E W [1995] Easton Pa., Mack Publishing Company, 19^(th) ed.) describes formulations that can be used in connection with the subject invention. It should be understood that in addition to the ingredients particularly mentioned above, the formulations of the subject invention can include other agents conventional in the art having regard to the type of formulations described herein.

In addition, Lactobacillus can be administered simultaneously or sequentially with an antioxidant that provides defenses against cellular oxidative damage. Suitable antioxidants include, but are not limited to, vitamins, minerals, peptides, enzymes, coenzymes, and metabolites, which are involved in the reduction of the oxidative stress in a subject. In one embodiment, the antioxidant is vitamin E. The term “vitamin E,” as used herein, includes, but is not limited to, eight different chemical forms: four tocopherols and four tocotrienols. In a specific embodiment, vitamin E is alpha-tocopherol. In certain embodiments, the antioxidant may be, for example, selenium, glutathione, vitamin C, vitamin E, carotenes (including beta carotene and retinol), or ubiquinone, or a combination thereof.

Strains of Lactobacillus reuteri are available from various public culture collections, including the American Type Culture Collection (ATCC, USA), ATCC 23272, 53608, 53609, 55148, and 55739; Deutsche Sammlung von Mikroorganismenn und Zellkulturen GmbH (DSMZ, Germany), DSM 8533, 17509, 20015, 20016, 20053, and 20056; Czechoslovak Collection of Microorganisms (CCM, Czech Republic), CCM 3625, 3642, 3643, 3644, and 3645; and National Collection of Industrial and Marine Bacteria (NCIMB, Scotland), NCIMB 11951, 701089, 701359, 702655, and 702656. Strains of Lactobacillus johnsonii are also available from various public culture collections, including the American Type Culture Collection (ATCC, USA), ATCC 332, 11506, and 33200; Deutsche Sammlung von Mikroorganismenn und Zellkulturen GmbH (DSMZ, Germany), DSM 10533 and 20553; Czechoslovak Collection of Microorganisms (CCM, Czech Republic), CCM 2935, and 4384; and National Collection of Industrial and Marine Bacteria (NCIMB, Scotland), NCIMB 8795, and 702241.

The Lactobacillus strain can be a mutant having substantially the same or improved properties or it can be a naturally-occurring variant thereof. Procedures for making mutants are well known in the microbiological art. Ultraviolet light and nitrosoguanidine are used extensively toward this end.

The composition of the subject invention can be administered in any suitable way, preferably orally. The pharmaceutically-acceptable carriers, additives, or excipients can be any suitable food products, such as milk, oats, wheat, corn, potatoes, green bananas, etc.

In one embodiment, the bacteria of the subject invention are administered in the form of a capsule (as dehydrated bacteria) as a food supplement. This will assure that the microorganisms survive through the gastrointestinal tract passage and exert their beneficial effect in the intestine.

Diet can be an important factor in the development of type 1 diabetes. For example, diets low in milk components or hydrolysed casein-based diets reduce the incidence of type 1 diabetes in BB-DP animals because protein components in milk have certain sequence identity to pancreatic antigens.

The subject invention further provides a method of preventing or slowing the development of T1D comprising administration of a composition comprising an effective amount of one or more Lactobacillus isolates together with diet modification.

Other autoimmune conditions to which the treatments of the subject invention may be applied include, but are not limited to, rheumatoid arthritis, multiple sclerosis, thyroiditis, inflammatory bowel disease, Addison's disease, pancreas transplantation, kidney transplantation, islet transplantation, heart transplantation, lung transplantation, and liver transplantation.

Therapeutic Benefits of Lactobacillus

The several mechanisms by which Lactobacillus can exert beneficial effects for the host include, but are not limited to, (i) as a physical barrier inhibiting the passage of inflammatory antigens, (ii) degradation of toxic components, (iii) release of nutrients and, (iv) production of anti-inflammatory compounds.

In addition, Lactobacillus strains may exert their beneficial effects through proteolytic activity by degradation of putative pro-diabetogenic components in the diet. Further, Lactobacillus strains, can hydrolyze the fiber components in the diet with the concomitant release of antioxidant compounds.

Lactobacillus Promotes Intestinal Barrier Function.

One beneficial effect of Lactobacillus is that it can promote intestinal barrier function, thereby inhibiting the passage of inflammatory antigens.

Lactobacillus can inhibit the growth of pathogenic bacteria. Lactobacillus can produce a direct inhibitory effect on enterobacteria, partially through host modifications in epithelial composition. The administration of Lactobacillus lowers Enterobacteriaceae counts in the cecum and colon. In stools the microbiota composition was not affected by the administration of L. johnsonii N6.2. However, a negative correlation between lactobacilli and enteric bacteria was found in the intestinal mucosa.

In addition, Lactobacillus is capable of preventing or reducing bacteria translocation in a subject. The early administration of Lactobacillus strains to BB-DP pups (2-7-day-old) decreased bacterial translocation to the spleen and liver, indicating that Lactobacillus produced a beneficial effect on the gastrointestinal epithelia.

Further, the administration of Lactobacillus can increase the level of goblet cells in a subject, thereby inhibiting enteric bacteria population. Goblet cells constantly produce mucus, which has a dual role of protecting the mucosa from adhesion of certain microorganisms to the epithelia while providing an initial binding site, nutrient source, and matrix on which bacteria can proliferate.

As exemplified herein, a higher number of goblet cells in the L. johnsonii fed and healthy control groups were observed compared to the diabetic group. The increase in goblet cells reflects higher mucus production.

Further, L. plantarum has a direct effect on epithelial cells by inducing secretion of mucins that diminish enteric pathogens binding to mucosal epithelial cells. Mucus production is a characteristic associated with animals that did not develop diabetes.

In addition, claudin-1 expression is induced following feeding of L. johnsonii, indicating a direct effect of the probiotic bacteria on intestinal barrier function.

Lactobacillus Facilitates the Release of Antioxidant Compounds.

A further beneficial effect of Lactobacillus is that it facilitates the release of antioxidant compounds by probiotic bacteria. The release of antioxidant compounds contributes to an enhanced oxidative stress response.

Adherence of Lactobacillus, such as for example, L. johnsonii to the intestinal epithelium, along with increased mucus secretion, decreases the passage of inflammatory compounds that irritate the mucosa and result in the generation of reactive oxygen species. Lactobacillus strains such as L. johnsonii are capable of targeting an early step in the signaling pathway, possibly Indoleamine 2,3-Dioxygenase (IDO), resulting in a more tolerogenic environment that reduces the overall oxidative stress environment conducive to a subsequent inflammatory response. As a result, Lactobacillus strains such as L. johnsonii can delay or prevent the onset of autoimmunity that leads to type 1 diabetes.

In addition, Lactobacillus species have cinnamic acid esterase activity, which makes them capable of alleviating oxidative stress and inflammation exhibited in diabetes. 80% of lactobacilli negatively correlated with the onset of diabetes in BB-DR rats have cinnamic acid esterase activity; while only 41% of the lactobacilli isolated from the BB-DP animals were positive.

Cinnamic acids are natural bioactive phenolic compounds extensively associated with anti-inflammatory and antioxidant properties. These acids (ferulic, di-ferulic, p-coumaric) are esterified in vegetable cell walls and consequently are assimilated by the intestinal tract only after microbiota-mediated enzymatic release. Small doses of ferulic acid decrease the incidence of diabetes in streptozotocin (STZ)-induced diabetic mice. Thus, phenolic compounds such as ferulic acid released by gut microbiota play a critical role in alleviating the oxidative stress and attenuating the hyperglycemic inflammatory response exhibited in diabetes.

Specifically, the L. johnsonii strain possesses two esterases that can release cinnamic and other phenolic compounds with anti-inflammatory properties. The release of cinnamic acids from dietary components can decrease diabetic incidents, as observed in the L. johnsonii N6.2 fed group in Example 11.

Advantageously, the administration of Lactobacillus according to the subject invention can produce an anti-oxidative effect in a subject. As described in Example 11, the oxidative status of the ileac mucosa was assessed by measuring the mRNA levels of genes involved in the oxidative stress response. The expression of enzymes involved in the detoxification of ROS will be induced if an oxidative environment is generated. The genes encoding Sod2, Gpx1, Cat, and GR were induced in diabetic animals; while their levels decreased in healthy animals. Gpx1 and Sod2 expression levels were even lower in the L. johnsonii N6.2 fed group, indicating a lower level of ROS.

In addition, the administration of Lactobacillus according to the subject invention can reduce the production of nitric oxide in a subject. Nitric oxide is a signaling molecule that links inflammation and the development of type 1 diabetes. An increased transcription and translation of the iNOS gene is associated with diabetes in BB-DP rats. The active participation of nitric oxide during the early stage of autoimmune diabetes was confirmed by specific inhibition of iNOS using aminoguanidine (AG). BB-DR rats treated with AG do not developed diabetes after Kilham rat virus (KRV) infection. As described in Examples 12-13, the expression level of iNOS (and its inducing cytokine, IFNγ) was down-regulated in the L. johnsonii N6.2 fed group, as compared to untreated diabetic rats.

The administration of Lactobacillus can also increase the levels of Cox-2 expression. Cox-2 has been reported to be mainly induced in activated macrophages and other inflammatory cells. The presence of Cox-2 and insulin in β-cells decreased during progression of diabetes in the non-obese diabetic (NOD) mouse model. The expression of Cox-2 (and their specific prostaglandins) has a general protective effect on a subject. In addition, the synthesis of cyclopentenone prostaglandins is determinant during inflammatory resolution.

As described in Example 11, the mRNA levels of Cox-2 in the small intestine were gradually increased in the healthy animals, with the highest expression in the L. johnsonii fed animals. The increase in Cox-2 expression correlates with a higher number of goblet cells in the intestine of healthy rats.

Timing of Treatment

The therapies of the subject invention can be used to alleviate type 1 diabetes.

In one embodiment, treatment is administered prior to the onset of clinical manifestation of overt type 1 diabetes. The time of administration is preferably before extensive irreversible beta cell destruction as evidenced by, for example, the clinical onset of type 1 diabetes.

As set forth in more detail below with respect to type 1 diabetes, those skilled in the art, having the benefit of the instant disclosure can utilize diagnostic assays to assess the stage of disease progression in a patient and then administer treatment at the appropriate time as set forth herein.

With regard to the early detection of type 1 diabetes, numerous autoantibodies have been detected that are present at the onset of type 1 diabetes. Also, new serologic markers associated with type 1 diabetes continue to be described. Four islet autoantibodies appear to be the most useful markers of type 1 diabetes: islet cell antibodies (ICA), insulin autoantibodies (IAA), glutamic acid decarboxylase autoantibodies (GADA), and insulinoma-associated-2 autoantibodies (IA-2A). These are discussed in more detail below; however, the use of these markers to identify those at risk for developing type 1 diabetes is well known to those skilled in the art. In a specific embodiment of the subject invention, treatment is administered when a patient has at least one antibody marker or, preferably, at least two of the antibody markers.

ICA serve an important role as serologic markers of beta-cell autoimmunity. Seventy percent or more of Caucasians are ICA-positive at onset of type 1 diabetes. Following diagnosis, ICA frequency decreases, and fewer than 10% of patients still express ICA after 10 years. The general population frequency of ICA is between 0.1% and 0.3%. In a preferred embodiment of the subject invention, ATG is administered prior to a decrease in ICA.

IAA occur in 35-60% of children at onset of type 1 diabetes but are less common in adults. For example, in Australians with new-onset type 1 diabetes, IAA were present in 90% of children less than 5 years old, in 71% of 5-10-year-olds, and in 50% of 10-15-year-olds. In Britons with type 1 diabetes, IAA were identified in 83% of children less than 10 years old and in 56% of children 10 years old and greater.

IAA have been detected in several other autoimmune diseases. IAA were identified in 15.9% of patients with Hashimoto's thyroiditis and 13.5% of Graves' disease subjects. In another study, IAA frequencies in various thyroid autoimmune diseases were 44% in Graves' disease, 21% in primary hypothyroidism, and 23% in chronic autoimmune thyroiditis, compared with 40% in primary adrenal failure, 36% in chronic hepatitis, 40% in pernicious anemia, 25% in rheumatoid arthritis, and 29% in systemic lupus erythematosus.

Approximately 2-3% of the general population express GAD autoantibodies. These antibodies are detected in 60% or more of new-onset cases of type 1 diabetes. The IA-2A and IA-2βA general population frequencies are similar to GADA at 2-3%. IA-2A and IA-2βA are observed in 60% or more of new-onset type 1 diabetes cases.

Early biochemical evidence of beta cell injury is a decreased first-phase insulin response to the administration of intravenous glucose (IVGTT). First-phase response is defined as the insulin concentrations at +1 and +3 min following completion of an intravenous bolus injection of glucose (e.g., 0.5 g/kg). There is also a dissociation in beta cell response to secretagogues: Initially the insulin response to intravenous amino acid administration (e.g., arginine) is preserved even while first-phase responses are deficient (Ganda, O. P. et al., 1984. “Differential sensitivity to beta-cell secretagogues in early, type 1 diabetes mellitus,” Diabetes 33: 516-521). In ICA-positive individuals eventually developing insulin-dependent diabetes, first-phase insulin release diminishes at a rate of about 20-40 μU/mL/year (Srikanta, S. 1984. “Pre-type 1 diabetes, linear loss of beta cell response to intravenous glucose,” Diabetes 33: 717-720).

When beta cell mass has substantially declined to less than 50% but more than 10% of normal, the OGTT may display abnormalities such as impaired fasting glucose (110-125 mg/dL) or impaired glucose tolerance (2-h glucose post-75-g challenge: 140-199 mg/dL). An abnormal OGTT prior to the clinical onset of type 1 diabetes is more likely observed in younger children. Frank clinical diabetes usually follows within 1-2 years of the onset of oral glucose intolerance. By the time acute symptoms of type 1 diabetes develop, beta cell mass is believed to have declined by approximately 90% or more from baseline. In one embodiment of the subject invention, treatment is administered once oral glucose intolerance is observed.

Most current procedures for the prediction of type 1 diabetes involve analyses of multiple islet autoantibodies. In every such study reported, nondiabetic individuals who express combinations of islet autoantibodies are found to be at greater risk for type 1 diabetes than individuals who express fewer varieties of islet autoantibodies. In addition, the total number of types of islet autoantibodies is usually more important than the specific combination of islet autoantibodies. In type 1 diabetes subjects, islet autoantibodies can also reappear after pancreas or islet transplantation, predicting failure to become insulin-independent (Bosi, E. et al. 2001. Diabetes 50:2464-2471).

Thus, in genetically predisposed individuals, an environmental trigger or triggers are believed to initiate beta cell autoimmunity, which can be identified by the presence of islet autoantibodies. With progressive beta cell damage, there is loss of first-phase insulin response to intravenous glucose administration. Subsequently the OGTT becomes abnormal, followed by symptoms of diabetes and the diagnosis of type 1 diabetes. Clearly the detection of islet autoimmunity can therefore be used as a predictive marker for the subsequent development of type 1 diabetes.

Both in nondiabetic relatives of type 1 diabetes subjects and in the general population, the detection of islet autoantibodies identifies individuals who are at high risk to develop subsequent type 1 diabetes (LaGasse, J. M. et al. 2002. Diabetes Care 25:505-511). Higher titers of ICA are more predictive than lower titers, and multiple islet autoantibodies are more powerful predictors than the presence of single autoantibodies. The combination of ICA plus low first-phase insulin secretion is possibly the strongest confirmed predictor of subsequent type 1 diabetes as demonstrated in the DPT-1. When using single autoantibodies, comparative sensitivities for the prediction of type 1 diabetes are as follows: ICA>GADA>IA-2A>>IAA. Combination islet autoantibody assays (e.g., the simultaneous detection of GADA and IA-2A (Sacks, D. B. et al. 2001. J. Clin. Chem. 47:803-804; Kawasaki, E. et al. 2000. Front Biosci. 5:E181-E190) will likely supersede ICA testing in future testing programs.

The majority of individuals with type 1 diabetes have islet autoantibodies at the time of onset of the disease. In cases where it is difficult to differentiate type 1 from type 2 diabetes, the presence of one or more islet autoantibodies (e.g., ICA, IAA, GADA, or IA-2A) is diagnostic of type 1a, immune-mediated diabetes (Rubinstein, P. et al. 1981. Hum. Immunol. 3:271-275). When individuals clinically present with a subtle, non-gketotic form of diabetes that may not be insulin-requiring yet are islet autoantibody-positive, LADA is diagnosed.

Materials and Methods Animals, Stool Sampling, and DNA Extraction

Two experiments were conducted with two independent sets of rats. In experiments 1 and 2, three and ten rats of each genotype were used, respectively. Stool samples were collected at 20, 30, and 70 days after birth. The genotypes were the bio-breeding diabetes-resistant (BB-DR) and the bio-breeding diabetes-prone (BB-DP) rats. In BB-DP rats, the onset of diabetes begins at 70 days. For animal housing, AALAC standards were used with 4 males or five females per cage under pathogen-free conditions. BB-DR and BB-DP rats were kept in separate cages but all rats were in the same room at the same temperature and light. All rats received the same water and food. All animals were put into an individual cage for the stool collection for about 4-5 hours to eliminate contamination from the stool of other animals. Rats were housed and samples obtained from Biomedical Research Models, Inc. (Worcester, Mass., USA).

After storage at −20° C. until DNA extraction, bacterial DNA was isolated from the stool samples using the FastDNA® Kit (Qbiogene Inc., Carlsbad, Calif.). After the DNA extraction, samples were purified with the DNeasy Tissue kit (Qiagen, Valencia, Calif.) following the manufacturer's instructions.

ARISA Analysis

Bacterial community composition was assessed by Automated Ribosomal Intergenic Spacer Analysis (ARISA), a culture-independent technique for constructing bacterial community fingerprints based on the length heterogeneity of the intergenic transcribed spacer region of bacterial rRNA operons (Fisher and Triplett, 1999; Bosshard et al., 2000). ARISA was modified by separating PCR products on a chip with an Agilent Bioanalyzer 2100 (Agilent Technology, Santa Clara, Calif.). In this study, ARISA profiles were assumed to be indicative of bacterial community composition, and differences in ARISA profiles were assumed to reflect variation in the composition of the respective bacterial communities.

PCR reaction was performed with the GOTAQ® PCR core system (Promega, Madison Wis.). The mixtures contained 5 μl of 10×PCR buffer, 200 μM dNTPs, 100 μM of each primer, 2.5 U of Taq polymerase, and approximately 100 ng of DNA template in a final volume of 50 μl. The primers used were S-D-Bact-1522-b-S-20 and L-D-Bact-132-a-A-18 (Ranjard et al., 2001). Reaction mixtures were held at 94° C. for 3 min, followed by 30 cycles of amplification at 94° C. for 45 s, 55° C. for 1 min., and 72° C. for 2 min. and a final extension of 72° C. for 7 min.

ARISA PCR products were purified with the QIAquick PCR Purification Kit (Qiagen, Valencia, Calif.). The amplification products fragments were then resolved by on-chip gel electrophoresis with an Agilent 2100 Bioanalyzer and the DNA LABCHIP® Kit 7500 (Agilent Technology, Santa Clara, Calif.). Size standards were also resolved in separate wells to estimate the size of each PCR product. The data were translated into gel-like images where peaks from the electropherograms are translated to appear as bands on a gel (FIG. 1). For each ARISA data set, the size, number, and area of peaks in the electropherograms were used to compare samples. Area peaks were standardized by dividing each single area peak by the total area of the peaks in the same sample.

To assess the degree of similarity among the samples, bacterial diversity and richness were calculated based on ARISA profiles. The bacterial diversity was estimated by using Shannon-Weaver index (H=sum (P_(i) ln [P_(i)]) where P_(i) is the number of a given species divided by the total number of species observed). The richness was estimated by using Margalef's index (d=(S−1)/log N) where S is the total number of species and N is the total number of individuals in the sample which provides a measure of species richness that is roughly normalized for sample size.

The Bray-Curtis similarity index was calculated to assess the degree of similarity among the samples and produce a similarity matrix. The resulting matrices with pairwise similarities were used to group samples that represented similar bacterial community composition. Hierarchical clustering was calculated by using complete linkage algorithm and the results were represented by a dendrogram with the x axis representing the full set of samples and the y axis defining a similarity level at which two samples were considered to have fused. All data analysis for the ARISA bands was conducted using the software PRIMER 6 version. 6.1.9 (PRIMER-E Ltd, Lutton, UK).

To identify the bacteria represented within specific ARISA bands, the PCR products were resolved on a 1.2% agarose gel and the appropriate bands excised. The bands were purified using the QIAEX®II Gel Extraction Kit (Qiagen, Valencia, Calif.). The purified fragments were cloned into a TOPO TA Cloning® (Invitrogen, Carlsbad, Calif.). Plasmids were purified with the QIAprep spin miniprep Kit (Qiagen, Valencia, Calif.) and the DNA fragments were cycle sequenced in both directions with T7 and T3 primers using DYEnamic ET terminator cycle sequencing kit (GE Healthcare), on a PTC200 thermocycler (BioRad) and run on a 96 well MegaBACE 1000 capilarity sequencer (GE Healthcare).

Vector sequence present in each sequence was eliminated using VecScreen. After elimination of potentially chimeric sequences, the nucleotide sequences were compared to all sequences in the NCBI database using Megablast (Altschul et al. 1997). Bacterial taxonomic affiliations were assigned based on the closest NCBI match. The criteria to assign a sequence to its closest relative were based on the best e-value (greater than 1e-50) and on the best bit-score (greater than 200). Sequences that did not match this criterion remained unclassified.

16S rRNA Gene Amplification, Cloning, and Sequencing

A fragment of 16S rRNA gene was amplified from the 60-day samples in order to confirm that the bacterial communities in both rat lines had differentiated by that time. To amplify the 16S rRNA gene fragments, primers 787f and 1492r were chosen (Roesch et al., 2007). The PCR conditions used were 94° C. for 2 minutes, 30 cycles of 94° C., 45s denaturation; 55° C., 45 s annealing; and 72° C., 1 min extension; followed by 72° C. for 6 minutes. The PCR products were cleaned, cloned into TOPO TA Cloning®, purified, sequenced, and sequences trimmed as described above. The sequences were aligned using ClustalX 1.83 (Thompson et al., 1997). Both weighted and unweighted UniFrac (Lozupone et al., 2006) were used to perform a Principal Coordinates Analysis (PCA) to find clusters of small groups of samples. The 16S rRNA gene sequences were classified using a Megablast search using the RDP II database. GenBank accession numbers EU812993 to EU814325 have been assigned to the DNA sequences obtained in this work.

16S rRNA Gene Amplification and Pyrosequencing

A fragment of 16S rRNA gene from the V9 region was amplified from the DNA extracted from the stool samples. We amplified the 16S rRNA gene fragments using the primers 787f and a modification of 1492r (Roesch et al., 2007). The primers were attached to the 454 LIFE SCIENCES® primer B and A (454 Life Sciences Corp., Branford, Conn.). The 454 run were multiplexed to obtain 16S rRNA sequences from twenty samples simultaneously. To do this, 8-base barcodes were added to the 5′-end of the reverse primers using the self-correcting barcode method of Hamady et al. (2008). For a list of primers and barcodes used see supplementary information. Six independent PCR reactions were performed for each sample. The PCR conditions used were 94° C. for 2 minutes, 25 cycles of 94° C., 45 s denaturation; 55° C., 45 s annealing; and 72° C., 1 min extension; followed by 72° C. for 6 minutes. The six PCR replications for each of 20 samples were combined and purified with the QIAquick PCR Purification Kit (Qiagen, Valencia, Calif.). The DNA concentration of the PCR product was then quantified by using on-chip gel electrophoresis with Agilent 2100 Bioanalyzer and DNA LABCHIP® Kit 7500 (Agilent Technology, Santa Clara, Calif.). Finally the reactions were combined in equimolar ratios to create a DNA pool that was used for pyrosequencing with primer B. The sequencing library was produced using the standard GS FLX library preparation procedure and two titration runs were performed. The average read length obtained was 215 bases. The maximum read length was 292. All reads were generated by GS FLX. All reads shorter than 100 were deleted from the analysis. The pyrosequences are deposited in GenBank as accession numbers FJ269364-FJ291326 and FJ291327-FJ313064 for the diabetes-prone sequences and FJ313065-FJ345302 for the diabetes-resistant sequences.

Data Preparation Prior to Further Analysis

Initially, all pyrosequencing reads were screened for quality and length of the sequences. The ends of the sequences that presented a Phred score smaller than 20 were trimmed and those reads that were shorter than 100 bases were removed from the dataset by using a program called Trim2 (Huang et al., 2006). The trimmed sequences were than screened for the 8-base barcode. A custom perl script was written to find the barcode and generate a new file for each sample. The sequences were then relabeled to denote the original sample.

Library Comparisons

For the overall comparison for significant differences among the bacterial communities evaluated, we first group the sequences from each sample into Operational Taxonomy Units (OTU's) (cutoff value for assigning a sequence to the same group was equal or greater than 97% similarity) using the program CD-HIT (Li and Godzik, 2006). Representative sequences (the longest sequence of the cluster) were chosen and merged in a single file. This file was used as input for MUSCLE (Edgar, 2004), which built a guide tree using UPGMA (Unweighted Pair Group Method with Arithmatic Mean) agglomerative clustering method. Quantitative and qualitative bacterial diversity measures were done using UniFrac (Lozupone et al., 2006). Unifrac analysis required a phylogenetic tree prepared using MUSCLE and the number of sequences found on each OTU in each sample. To assess the qualitative and quantitative diversity of the bacterial communities unweighted and weighted UniFrac were used, respectively. Unifrac Principal Coordinates Analysis (PCA) was performed in order to find clusters of similar groups of samples. PCA is an ordination method based on multivariate statistical analysis that maps the samples in different dimensions and reflects the similarity of the biological communities. A matrix using the UniFrac metric for each pair of environments is calculated. The distances are turned into points in space with the number of dimensions one less than the number of samples. The first three principal dimensions were used to plot a 3-dimensional graph (FIG. 2).

Similarity Among Communities Based on Membership and Structure

In order to identify the organisms whose abundance differs between the BB-DP and BB-DR samples, sequence libraries were combined and each sequence was assigned to an Operational Taxonomic Unit (OTU) at 95% and 97% similarity by using CD-HIT (Li and Godzik, 2006). The number of sequences in each OTU found in each sample was used to construct a table with OTU's (lines) and samples (columns). This operation was performed by using a custom script written in PHP/HTML. The script uses as input the .clstr file from CD-HIT. The input data is stored in a database were the data is organized in two columns. The first column represents the sample name and the second represents the OTU number. Using mysql statements all the data contained for each OTU is collected and compared with an array that contains all of the sample names. The list grows with each new match found. After all comparisons are finished, all OTUs are phylogentically classified.

Phylogenetic Classification of 16S rRNA Gene Fragments

The 16S rRNA gene sequences were phylogenetically classified using blast searches against the RDP II database. The closest bacterial relatives were assigned according to their best matches to sequences in the database using an e-value threshold equal to or less than 10⁻²⁰ and a bit score equal to or greater than 200.

To determine whether specific bacterial genera or species differed between BB-DP and BB-DR rats, an exact Chi-square test (based on 50000 Monte Carlo iterations) was performed to get a p-value for the null hypothesis that there was no difference between the resistant and prone rats. The exact test, which is based on permutations, is not sensitive to zero counts in the bacterial relatives. The p-values were ordered and processed to find a false discover rate (FDR) cutoff of 1%.

Real-Time Quantification of Total Bifidobacterium and Lactobacillus Load

The DNA extracts were each used as a template for two separated PCRs using primers first described by Delroisse et al. (2006). The primers used are F-lacto (5′-gaggcagcagtagggaatcttc-3′ (SEQ ID NO:1)), R-lacto (5′-ggccagttactacctctatccttcttc-3′ (SEQ ID NO:2)), F-bifido (5′-cgcgtcyggtgtgaaag-3′ (SEQ ID NO:3)) and R-bifido (5′-ccccacatccagcatcca-3′ (SEQ ID NO:4)). Quantitative PCRs were performed in a reaction volume of 20 ul containing lx Fast Start Sybr Green Master Mix (Roche Diagnostics, Indiana, USA), 200 nM each forward and reverse primers, and 5 ng of DNA extracted from the stool samples. Amplification and detection of DNA were performed with the iCycler detection system (BioRad) with optical grade 96-well PCR plates and optical film. The reaction conditions were 50° C. for 2 min and 95° C. for 10 min, followed by 45 cycles of 95° C. for 15 s and 62° C. for 1 min. Data analysis was conducted with the software supplied by BioRad. Purified genomic DNA in the range 10 fg to 1 ng of Lactobacillus reuteri were used as the standard for determining the amount of Lactobacillus or Bifidobacterium DNA by real-time PCR. Using L. reuteri DNA as a standard for both genera is appropriate given that both have similar genome sizes. DNA concentrations were determined with the Nanodrop™ spectrophotometer.

Calculation of Bacterial Cell Numbers Following Quantitative PCR

The conversion of the amount of Lactobacillus and Bifidobacterium DNA into cell numbers in the stool samples was determined as described by Byun et al. (2004). In this method, an average genome size of 2.2 Mb is assumed along with similar 16S rRNA gene copy numbers (Klaenhammer et al., 2002; Makarova et al., 2006). With these parameters, each cell is assumed to contain approximately 2.4 fg of DNA (Byun et al., 2004).

Primers and Barcode Sequences Used Forward Primer

The underlined sequence is 454 Life Sciences® primer B, and the bold sequence is the bacterial primer 787f. The TC, in italics, is a two-base linker sequence that helps to mitigate any effect the composite primer might have on PCR efficiency.

(SEQ ID NO: 5) B- 5′-GCCTTGCCAGCCCGCTCAG TC ATTAGATACCCNGGTAG -3′

Reverse Primer

The underlined sequence is 454 Life Sciences® primer A, and the bold sequence is the bacterial primer 1492r. The next eight-base sequence designates the barcode and the “TC”, in italic, is a linker between the barcode and rRNA primer that helps to mitigate any effect the composite primer might have on PCR efficiency.

(SEQ ID NO: 6) A1-5′ -GCCTCCCTCGCGCCATCAGAAGCCGTTTC GNTACCTTGTTACG ACTT-3′ (SEQ ID NO: 7) A2-5′ -GCCTCCCTCGCGCCATCAGACACACACTC GNTACCTTGTTACG ACTT-3′ (SEQ ID NO: 8) A3-5′ -GCCTCCCTCGCGCCATCAGAGACACAGTC GNTACCTTGTTACG ACTT-3′ (SEQ ID NO: 9) A4-5′ -GCCTCCCTCGCGCCATCAGATAACCGCTC GNTACCTTGTTACG ACTT-3′ (SEQ ID NO: 10) A55′ -GCCTCCCTCGCGCCATCAGCAACACCATC GNTACCTTGTTACGA CTT-3′ (SEQ ID NO: 11) A6-5′ -GCCTCCCTCGCGCCATCAGCCAACCAATC GNTACCTTGTTACG ACTT-3′ (SEQ ID NO: 12) A7-5′ -GCCTCCCTCGCGCCATCAGCGAACCATTC GNTACCTTGTTACG ACTT-3′ (SEQ ID NO: 13) A8-5′ -GCCTCCCTCGCGCCATCAGCTACACCTTC GNTACCTTGTTACG ACTT-3′ (SEQ ID NO: 14) A9-5′ -GCCTCCCTCGCGCCATCAGGAACACCTTC GNTACCTTGTTACG ACTT-3′ (SEQ ID NO: 15) A10-5′ -GCCTCCCTCGCGCCATCAGGCAACCATTC GNTACCTTGTTAC GACTT-3′ (SEQ ID NO: 16) A11-5′ -GCCTCCCTCGCGCCATCAGGGAACCAATC GNTACCTTGTTAC GACTT-3′ (SEQ ID NO: 17) A12-5′ -GCCTCCCTCGCGCCATCAGGTACACCATC GNTACCTTGTTAC GACTT-3′ (SEQ ID NO: 18) A13-5′ -GCCTCCCTCGCGCCATCAGTAATCCGGTC GNTACCTTGTTAC GACTT-3′ (SEQ ID NO: 19) A14-5′ -GCCTCCCTCGCGCCATCAGTCACACAGTC GNTACCTTGTTAC GACTT-3′ (SEQ ID NO: 20) A15-5′ -GCCTCCCTCGCGCCATCAGTGACACACTC GNTACCTTGTTAC GACTT-3′ (SEQ ID NO: 21) A16-5′ -GCCTCCCTCGCGCCATCAGTTAACCGGTC GNTACCTTGTTAC GACTT-3′ (SEQ ID NO: 22) A17-5′ -GCCTCCCTCGCGCCATCAGAAGGATCGTC GNTACCTTGTTAC GACTT-3′ (SEQ ID NO: 23) A18-5′ -GCCTCCCTCGCGCCATCAGACCATGCATC GNTACCTTGTTAC GACTT-3′ (SEQ ID NO: 24) A19-5′ -GCCTCCCTCGCGCCATCAGAGACAGTGTC GNTACCTTGTTAC GACTT-3′ (SEQ ID NO: 25) A20-5′ -GCCTCCCTCGCGCCATCAGCAACTGCATC GNTACCTTGTTAC GACTT-3′ Following is a list of near-neighbors bacterial isolates presented in FIG. 5 that were used to construct the phylogeny with the unclassified 16S rRNA sequences. The accession number in the Gene Bank precedes the isolate's name. AAVC01000013.1 Clostridium cellulolyticum str. H10 AAVO02000010.1 Ruminococcus obeum str. ATCC 29174 AB021701.1 Mogibacterium pumilum str. ATCC 700696 AB053941.1 Tannerella forsythensis str. HG3 AB053942.1 Tannerella forsythensis str. KM3 AB075772.1 Clostridium sphenoides str. ATCC 19403 AB093546.1 Clostridium sp. str. JC3 AB100838.1 Heliorestis baculata str. DSM 13446 AB117566.1 Clostridium hylemonae str. CT-9 AB158767.1 Lactobacillus vaginalis str. MF2123 AB238922.1 Parabacteroides distasonis str. JCM 5825 AB244773.1 Prevotella copri str. CB28 AB370251.1 Barnesiella intestinihominis str. YIT 11860 ABFK02000017.1 Alistipes putredinis str. DSM 17216 ABGD02000031.1 Anaerotruncus colihominis str. DSM 17241 AF016691.1 Acidaminobacter hydrogenoformans str. glu 65 AF028349.1 Clostridium fusiformis CM973 AF030449.1 Ruminococcus flavefaciens str. ATCC 49949; C52 AF030451.1 Ruminococcus albus str. ATCC 27211; 20 AF079102.1 Heliorestis daurensis str. BT-H1 AF092549.1 Clostridium algidixylanolyticum str. SPL73 AF126687.1 Clostridium fimetarium str. Z-2189; DSM 9179 AF157050.1 Lactobacillus sp. ASF360 str. ASF 360 AF202262.1 Pseudobutyrivibrio ruminis str. pC-XS7 AF202264.1 Syntrophococcus sucromutans str. S195

AF227870.1 Bifidobacterium sp. str. 65947

AF243154.1 Lactobacillus vaginalis str. KC19 AF262239.1 Clostridium leptum str. 10900 AF287759.1 Bifidobacterium sp. oral strain str. A32ED oral

AF319778.1 Bacteroides sp. str. 139

AF418173.1 Desulfococcus multivorans str. DSM 2059 AF481229.1 Prevotella sp. str. E9_42 AJ002591.1 Clostridium sp. str. DSM 10643 Lip1 AJ222546.1 Anaerobacter polyendosporus AJ270469.2 Faecalibacterium prausnitzii str. A2-165

AJ311620.2 Clostridium hathewayi str. DSM 13479=CCUG 43

AJ318527.2 Bryantella formatexigens 1-52 AJ413954.1 Faecalibacterium prausnitzii str. ATCC 27768 AJ428553.1 Butyrivibrio hungatei str. JK 615 AJ505973.1 Bryantella formatexigens 1-52 AJ506115.1 Clostridium estertheticum subsp. laramiense str. DSM 14864 subsp. AJ508452.1 Clostridium bolteae str. 16351 AM915269.1 Ruminococcus flavefaciens str. C94=ATCC 19208 AY136666.1 Bacteroides capillosus str. ATCC 29799 AY169414.1 Lachnospira pectinoschiza AY169415.1 Clostridium nexile AY169422.1 Clostridium clostridioforme AY178843.1 Pseudobutyrivibrio ruminis str. Ce4 AY244776.1 Haloanella gallinarum str. 2002-2301269 AY331143.1 Mahella australiensis str. 50-1-BON AY347530.1 Butyrivibrio fibrisolvens str. 0/10 AY353957.1 Clostridium amygdalinum str. BR-10 AY445598.1 Ruminococcus flavefaciens str. R13e2 AY518589.1 Acetanaerobacterium elongatum str. Z1 AY552788.2 Clostridium hathewayi AY603000.2 Thermoincola carboxydophila str. 2204 AY643492.1 Dysgonomonas wimpennyi str. ANFA2 AY689228.1 Prevotella nigrescens str. ChDC KB6 AY689229.1 Prevotella nigrescens str. ChDC KB50 AY699273.1 Butyrivibrio fibrisolvens M55 AY699274.1 Butyrivibrio fibrisolvens L8 AY730663.1 Clostridium orbiscindens str. NML 00-082 AY804150.1 Roseburia faecalis str. M88/1 AY878326.1 Clostridium scindens AY959944.2 Clostridium alkalicellum str. Z-7026

AY960568.1 Anaerostipes sp. str. 1E4

CP000139.1 Bacteroides vulgatus str. ATCC 8482 CP000139.1 Bacteroides vulgatus str. ATCC 8482 CP000140.1 Parabacteroides distasonis str. ATCC 8503 CP000141.1 Carboxydothermus hydrogenoformans str. Z-2901 CP000705.1 Lactobacillus reuteri F275 str. DSM 20016 D89329.1 Bifidobacterium subtile str. JCM 7109 D89330.1 Bifidobacterium saeculare str. DSM6533 DQ278862.1 Clostridium aminophilum 152R-1b DQ358727.1 Paenibacillus zanthoxylum str. JH95 DQ882649.1 Ruminococcus bromii str. YE282 EF025906.1 Clostridium coccoides str. 8F EF100911.1 Caldicellulosiruptor kronotskiensis str. 2902 EF408243.1 Clostridium hathewayi EF533992.1 Lactobacillus acidophilus str. IDCC 3301 EF680276.1 Clostridium thermocellum str. JN4 EU109732.1 Chryseobacterium sp. str. B2 EU252503.1 Dysgonomonas sp. str. AM15 L09174.1 Clostridium stercorarium L09175.1 Clostridium sporogenes str. RT51 B1 L35516.1 Acetivibrio cellulolyticus M59083.1 Acetitomaculum ruminis str. 139B NC_004193.1 Oceanobacillus iheyensis str. HTE831 NZ_AAVO02000010.1 Ruminococcus obeum str. ATCC 29174 NZ_AAXA02000014.1 Dorea formicigenerans str. ATCC 27755 NZ_ABAX03000023.1 Anaerostipes caccae str. DSM 14662 NZ_ABFK02000017.1 Alistipes putredinis str. DSM 17216 U30147.1 Lawsonia intracellularis str. NCTC 12657 U77343.1 Butyrivibrio fibrisolvens str. OR79 X71846.1 Clostridium aldrichii str. DSM 6159 X71853.1 Clostridium populeti str. ATCC 35295 X73438.1 Clostridium cellulovorans str. DSM 3052 X73449.1 Clostridium sphenoides str. DSM 632 X75272.1 Clostridium grantii X76161.1 Clostridium aminobutyricum str. DSM 2634 X76163.1 Clostridium aerotolerans str. DSM 5434 X76328.1 Lactobacillus reuteri str. DSM 20016 T X76747.1 Clostridium sp str. DSM 6877(FS41) X77839.1 Clostridium polysaccharolyticum str. DSM 1801 X77840.1 Oxalophagus oxalicus str. DSM 5503 X83430.1 Ruminococcus flavefaciens str. NCFB 2213 X85098.1 Ruminococcus albus X85099.1 Ruminococcus bromii X85100.1 Ruminococcus callidus X87152.1 Johnsonella ignava str. ATCC 51276 X89973.1 Butyrivibrio fibrisolvens str. NCDO 2432 X89981.1 Butyrivibrio crossotus str. NCDO 2416 X94965.1 Ruminococcus schinkii str. B; CIP 105464; DSM 10518 X95893.1 Pseudobutyrivibrio ruminis str. DSM 9787 X96736.1 Clostridium pascui str. DSM 10365 (cml9) Y10584.1 Clostridium sp. str. formate Y11568.1 Desulfotomaculum guttoideum str. DSM 4024 Y11574.1 Desulfotomaculum thermobenzoicum str. DSM 6193 Y14581.1 Oxalophagus oxalicus str. DSM 5503T Y18176.1 Clostridium disporicum str. DSM 5521 Y18180.1 Clostridium thermosuccinogenes str. DSM 5807 Y18185.1 Clostridium saccharolyticum str. DSM 2544 Y18186.1 Clostridium scindens str. DSM 5676 Y18214.1 Desulfonispora thiosulfatigenes str. DSM 11270 Y18530.1 Dysgonomonas gadei str. 1145589 Z49863.1 Sporobacter termitidis str. SYR

Bacterial Strains

Bacterial strains, Lactobacillus johnsonii N6.2 and Lactobacillus reuteri TD1, were isolated from BB-DR rats. Lactobacilli strains were grown in MRS (de Man, Rogosa and Sharpe) broth (REMEL, Lenexa, USA) at 37° C.

Analysis of the Intestinal Microflora by Real-Time Quantification

Viability counts were performed on samples taken from colonic content. Samples were immediately placed in 5 ml of sterile PBS buffer and viable counts for Lactobacilli, Bacteroides, anaerobes and enterobacteria were determined as described in Taranto et al. (2008), which is hereby incorporated by reference in its entirety.

For real-time quantification of microbial loads, DNA was extracted from samples preserved at −80° C. in RNAlater® solution (Ambion, Austin, Tex.), as described in Roesch et al. (2009), which is hereby incorporated by reference in its entirety. DNA extraction was performed using the QIAamp DNA Stool Mini kit (Qiagen Sciences, city, MD) following the manufacturer's instructions.

Selected groups of the rat fecal microbiota were measured using DNA extracts from each rat for RT-qPCR. Primer sequences for Real-time Quantification of microbial loads by RT-qPCR are based on the 16S rRNA, and are listed as follows.

SEQ ID NO TARGET NAME SEQUENCE SOURCE 26 Bacteria F_Bact 1369 CGGTGAATACGTTCCCGG 5 27 R_Prok 1492 TACGGCTACCTTGTTACGACTT 28 Lactobacillus F-lacto GAGGCAGCAGTAGGGAATCTTC 6 29 R-lacto GGCCAGTTACTACCTCTATCCTTCTTC 30 Bacteroides AllBac296F GAGAGGAAGGTCCCCCAC 7 31 AllBac412R CGCTACTTGGCTGGTTCAG 32 Clostridium Ccoc 07 GACGCCGCGTGAAGGA 5 33 Ccoc 14 AGCCCCAGCCTTTCACATC 34 Enterobacteriaceae En-lsu-3F TGCCGTAACTTCGGGAGAAGGCA 3 35 En-lsu-3R TCAAGGACCAGTGTTCAGTGTC 36 Enterococcus g-Encoc-F ATCAGAGGGGGATAACACTT 3 37 g-Encoc-R ACTCTCATCCTTGTTCTTCTC 38 Pseudomonas PSD7F CAAAACTACTGAGCTAGAGTCG 3 39 PSD7R TAAGATCTCAAGGATCCCAACGGCT 40 Staphylococcus STPYF ACGGTCTTGCTGTCACTTATA 3 41 STPYR2 TACACATATGTTCTTCCCTAATAA 42 Bifidobacterium F-bifido CGCGTCYGGTGTGAAAG 6 43 R-bifido CCCCACATCCAGCATCCA

Quantitative PCR was performed with 1×iQ SYBR Green Supermix (Bio-Rad, Hercules, Calif.), 200 nM forward and reverse primers, and 5 ng of stool sample DNA. DNA concentrations were determined with the Nanodrop™ spectrophotometer. Amplification and detection of DNA were performed in duplicate with the iCycler detection system (BioRad). Reaction was performed under the following conditions: 50° C. for 2 min, 95° C. for 10 min, followed by 45 cycles of 95° C. for 15 sec and 62° C. for 1 min.

Data analysis was conducted with Bio-Rad software. DNA amplification standard curves were constructed using purified genomic DNA in the range 10 fg to 1 ng of Lactobacillus reuteri, L. johnsonii, Staphylococcus sp., Bacteroides dorei and E. coli, as described in Roesch et al. The conversion of DNA amounts into cell numbers was determined considering the genome size for each bacteria and the copy number of the 16S RNA gene, as described in Byun et al. (2004) and Matsuda et al. (2007), which are hereby incorporated by reference in their entirety.

Real-Time qPCR of Host Responses

DNA and RNA extractions from samples preserved at −80° C. in RNALATER® solution (Ambion, Austin, Tex.) were performed using the Ilustra™ TriplePrep kit (GE Health care, UK) following the manufacturer's instructions. cDNA was synthesized using iScript™ cDNA synthesis kit (Bio-Rad) and qRT-PCR were performed.

Primer sequences for host response by RT-qPCR are listed as follows.

SEQ ID NO TARGET NAME SEQUENCE SOURCE 44 β-actin β-actin Fw TGACAGGTGCAGAAGGAGA 8 45 β-actin Rv TAGAGCCACCAATCCACACA 46 Claudin-1 Cldn-1_Fw AGGTCTGGCGACATTAGTGG 9 47 Cldn-1_Rv TGGTGTTGGGTAAGAGGTTG 48 Occludin Occludin_Fw GCTCAGGGAATATCCACCTATCA 10 49 Occludin_Rv CACAAAGTTTTAACTTCCCAGACG Transforming Growth 50 Factor-β TGFB_Fw GGACTACTACGCCAAAGAAG 11 51 TGFB_Rv TCAAAAGACAGCCACTCAGG 52 Interferon-γ IFNγ_Fw AGGATGCATTCATGAGCATCGCC 12 53 IFNγ_Rv CACCGACTCCTTTTCCGCTTCCT 54 Tumor Necrosis TNF-a_Fw TCTTCTCATTCCTGCTCGTG 13 55 Factor-α TNF-a_Rv GATGAGAGGGAGCCCATTT Inducible Nitric Oxide 56 Synthase iNOS_Fw CTCACTGTGGCTGTGGTCACCTA 8 57 iNOS_Rv GGGTCTTCGGGCTTCAGGTTA 58 Glutathione GPX1_Fw CGGTTTCCCGTGCAATCAGT 14 59 Peroxidase 1 GPX1_Rv ACACCGGGGACCAAATGATG 60 Catalase CAT_Fw CGACCGAGGGATTCCAGATG 14 61 CAT_Rv ATCCGGGTCTTCCTGTGCAA 62 Glutathione GR_Fw AGCCCACAGCGGAAGTCAAC 14 63 Reductase GR_Rv CAATGTAACCGGCACCCACA 64 Superoxide SOD1_Fw GCGGTGAACCAGTTGTGGTG 14 65 Dismutase 1 SOD1_Rv AGCCACATTGCCCAGGTCTC 66 Superoxide SOD2 Fw AGCTGCACCACAGCAAGCAC 14 67 Dismutase 2 SOD2_Rv TCCACCACCCTTAGGGCTCA 68 Cyclooxygenase-2 COX2_Fw CTCTGCGATGCTCTTCCGAG 15 69 COX2_Rv AAGGATTTGCTGCATGGCTG Indolcamine 2,3- 70 Dioxygenase IDO_Fw GCTGCCTCCCATTCTGTCTT 16 71 IDO_Rv TGCGATTTCCACCATTAGAGAG

Intestinal Morphology

Intestinal injury was evaluated by histology. Neutral buffered formalin (10%, V/V) fixed ileum samples were embedded in paraffin, cut into 4 μm sections, mounted on glass slides, and stained with hematoxylin and eosin according to standard procedures. Villus height, width and crypt depth were measured using a Nikon microscope (Universal Imaging Corp., Westchester, Pa.) with an ocular micrometer.

The intestinal injury was evaluated using a semiquantitative scoring system ranging from 0 to 4 modified according to Arumugam et al. (2003), which is hereby incorporated by reference in its entirety. Normal mucosa was scored as grade 0. Epithelial cell damages, including loss of cells and separation of the epithelial cells from the underlying villus were scored between grades 1-3; while loss of villus tissue was scored as grade 4. Intestinal sections were also analyzed for goblet cells numbers per total cells within a villus. For each animal, counts from 6 villi for each slide in three different regions of the slide were averaged.

Western Blot Analysis of iNOS Expression

Protein expression was analyzed using whole cell lysates. Rat ileum samples were weighed, minced, and disaggregated by incubation at 250 rpm and 37° C. in PBS (1:2, w/v) with 0.25% collagenase. Samples were immediately placed on ice and homogenized by vortexing with glass beads (Sigma Life Science) containing Complete Mini Protease Inhibitor Cocktail (Roche, Mannheim, Germany). Samples were centrifuged at 13,000×g for 10 min at 4° C.

Protein concentration was determined by Bradford method (Bio-Rad Protein Assay). 40 ug of protein per sample was separated using sodium dodecyl sulfate-polyacrylamide electrophoresis and transferred onto Nitroplus membranes (MSI, Flanders, Mass.) using a semi-dry transfer method. Membranes were blocked for 1 hr in phosphate buffered saline with 0.075% tween 20 (T-PBS) and 5% milk. Membranes were incubated with mouse anti-iNOS antibody (1:1000) or mouse anti-β-actin (1:10,000) (Abcam, Cambridge, Mass.) in T-PBS at 4° C. overnight, and subsequently washed twice in T-PBS for five minutes. Incubation in horseradish peroxidase-conjugated anti-mouse antibody was performed for 1 hr and signal was detected using enhanced chemiluminescent system (Amersham Pharmacia Biotech). β-actin was utilized as an internal control.

Hexanoyl-Lys Enzyme-Linked Immunosorbent Assay

Relative lipid peroxidation was determined by analyzing hexanoyl-lys levels by ELISA on rat ileum cell suspensions. Twenty mg of each rat ileum sample was finely minced on a cold glass slide and suspended in 300 μl 1×PBS+0.25% collagenase type I (Invitrogen, Carlsbad, Calif.). Samples were vortexed vigorously at 5 min intervals while incubating at 37° C. for 30 min. Free-cell suspensions were separated from remaining connective tissue fractions after incubation.

Cell concentration was determined by optical density at 600 nm using a Syngery HT microplate reader (BioTek Instruments, Winooski, Vt.). Each sample was split into 1 ml aliquots (control and experimental sets), pelleted at 5000 rpm, and washed with 1 ml 1×PBS twice. Cell pellets were resuspended in 100 μl of lx PBS. 100 μl of 1×PBS was added to the control set, and 100 μl of 1×PBS+2 μg/ml hexanoyl-lysine monoclonal antibody (JaICA, Shizuoka, Japan) was added to the experimental set. Samples were incubated at 37° C. for 1 h, followed by two washes in 1×PBS. 100 ul of 1×PBS+80 ng/ml of peroxidase labeled anti-mouse monoclonal antibody (Amersham Pharmacia Biotech, Pittsburgh, Pa.) was added to both sets and incubated for 1 hr at 37° C.

Following incubation, cells were washed twice and resuspended in 100 ul 1×PBS. A 20 mM reaction mixture of o-Phenylenediamine (Sigma, St. Louis, Mo.) was prepared in a 50 mM phosphate citrate buffer pH=5 and kept dark. Immediately before reading, 30% H₂O₂ was added to the reaction mixture to a final concentration of 0.04%. To each sample, 100 ul of reaction mixture was added, and samples were read continuously at 450 nm and 570 nm for 30 min using Syngery HT microplate reader (BioTek Instruments, Winooski, Vt.). Specific activity was calculated as the amount of product (μmol·min⁻¹) and normalized for cell density. This assay was performed in triplicate for at least three animals in each group.

Statistical Analysis

Statistical analysis was performed utilizing the t-test for unpaired data or by the nonparametric Mann-Whitney. Differences with P<0.05 were considered significant. Data was analyzed by GraphPad Prism (GraphPad Software, San Diego, USA).

Following are examples which illustrate procedures for practicing the invention. These examples should not be construed as limiting. All percentages are by weight and all solvent mixture proportions are by volume unless otherwise noted.

Example 1—Direct Sequence Analysis of Arisa Bands

Two dominant peaks, 600 to 640 bp in size, were found in all the BB-DP samples but not in the BB-DR samples (FIG. 1). A dominant 370-bp peak was also found in all BB-DR samples that was not present among the stool samples from diabetes prone rats (FIG. 1). All three of these bands were excised from agarose gels and sequenced. A total of 247 sequences were obtained for the BB-DP specific 600- and 640-bp bands. The sequencing analysis showed that these bands were derived from strains of Bacteroides, Xanthomonas and Acinetobacter. The genera Bacteroides made up 44.9% of the sequences while Xanthomonas and Acinetobacter were found in 15.8 and 14.5% of the sequences tested, respectively. A total of 266 sequences were obtained for the 370-bp band that was BB-DR specific. Lactobacillus strains were the source of 92.8% of the sequences with the remaining sequences derived from Clostridium, Flexibacter and Porphyromonas. These results suggested that Lactobacillus may be more common in BB-DR than BB-DP and that Bacteroides may be more common in BB-DP.

Example 2—Comparison of the Bacterial Communities in BB-DR and BB-DP Based on 16S RRNA Library Comparison

An average of 138 16S rRNA sequences were obtained from the six stool samples from experiment 1. These sequences were aligned to prepare a distance matrix by calculating pairwise UniFrac values (Lozupone et al. 2006) for each BB-DP and BB-DR sample at 60 days of age. Principal coordinates analysis (PCA) of the matrix was constructed using UniFrac. As the number of OTUs are correlated with the amount of sampling effort (Hughes et al., 2001; Roesch et al., 2007), a simple comparison of the number of OTUs between groups can lead to misinterpretations due to undersampling or to variability between individuals rather than variability between groups. To avoid this problem, quantitative and qualitative bacterial diversity measures were calculated by using Principal Coordinates Analysis (PCA). This approach compares the communities for significant differences using phylogenetic information and multivariate statistical techniques for finding the most important axes along which the samples vary. In this study, PCA was also used to find clusters of samples that represent similar bacterial communities (FIG. 2).

PCA showed that the BB-DP communities were far more similar to each other than they were to any of the BB-DR communities (FIG. 2A). The BB-DP and BB-DR communities differed at the 1% level of confidence as measured using either weighted or unweighted UniFrac. Thus, the bacterial community composition differed whether or not the abundance of taxa was considered.

Example 3—Analysis of Bacterial Community Composition in Diabetes-Prone and Diabetes-Resistant Samples

The results of experiment 1 encouraged a second experiment with more replicates per genotype and higher throughput 16S rRNA sequencing. The first analysis of the pyrosequencing data was to determine whether the bacterial communities found in the 20 rats at 70 days after birth differed significantly between the BB-DR and BB-DP rats. This was done by PCA as described above in experiment 1 (FIG. 2B).

The weighted and unweighted UniFrac analyses showed that the bacterial community composition in the stool of diabetes-prone and diabetes-resistant rats was significantly different at the 1% level of confidence. The Shannon-Weaver and richness diversity indices were calculated for each time point in experiment 2 using the ARISA profiles (FIG. 3). The diversity indices did not change significantly over time in the BB-DR samples but did decline by 70 days in the BB-DP samples. There was no significant difference in diversity between the 20- and 30-day samples in B-EP or BB-DR.

Example 4—Identification of the Bacteria that Vary Between the Diabetes-Prone and Diabetes-Resistant Samples

Having found statistically significant differences between bacterial communities in BB-DP and BB-DR rats (FIGS. 1 and 2), the next step was to identify those bacterial genera and species that were responsible for the differences observed. To determine the types of intestinal bacteria associated with TD1, we assigned the 16S rRNA sequences to closest bacterial relatives according to their best matches to sequences of known organisms by using BLAST search (Altschul, et al. 1997). Twenty 16S rRNA libraries were obtained by multiplex pyrosequencing and ranged in size from 1,261 to 7,997 sequences (Hamady et al. 2008; Table 4). Sequences within each library were compared and operational taxonomic units (OTUs) were identified using 95% or 97% similarity as criteria for assigning sequences to approximate the same genus or species, respectively. For the diabetes-prone samples, the number of operational taxonomic units (OTUs) at the 97% similarity level varied from 327 to 1,210 with an average of 748. For the diabetes-resistant samples, the number of OTUs varied from 270 to 1,689 with an average of 724.

The proportion of total reads that could be assigned to known genera was 22.33% and 23.65% of the BB-DP and BB-DR reads, respectively, using the 95% similarity level to define a genus. The proportion of total reads that could be assigned to known species was 12.06% and 13.23% of the BB-DP and BB-DR reads, respectively, using the 97% similarity level to define a species.

The bacterial communities were compared at the genus and species level with 74 bacterial genera and 124 bacterial species identified as inhabitants of the rat stools tested. To test which genera or species were different between resistant and prone rats, an exact Chi-square test showed that 24 bacterial species and 18 bacterial genera differed in abundance at the 1% level of confidence between diabetes-prone and diabetes-resistant samples (Tables 1 and 2). Those species and genera that did not differ are also presented (Tables 5 and 6). The most abundant genera found in these samples were Clostridium and Bacteroides. The abundance of the Bacteroides differed significantly between the diabetes-prone and diabetes-resistant samples while the clostridia did not change (Table S5). Five species of Clostridium were more abundant in BB-DP while one species was more abundant in BB-DR (Table 2).

Based on the exact Chi-square test, 9 genera were found to be statistically significantly higher in abundance in the BB-DP samples but statistically significantly lower in abundance or absent in the BB-DR samples (Table 1). Those genera were: Bacteroides, Eubacterium, Halothermothrix, Ruminococcus, Anaerostripes, Mucispirillum, Butyrivibrio, Pediococcus, and Sporobacter. Of these, Bacteroides, Eubacterium and Ruminococcus were the most abundant in the BB-DP samples with 6.73, 4.00, and 2.30%, respectively of the total number of sequences.

In BB-DR rats, 9 bacterial genera were found in statistically greater numbers than in the BB-DP samples (Table 1). Those genera include Bifidobacterium, Lactobacillus, Prevotella, Pseudobutyrivibrio, Spiroplasma, Proteiniphilum, Streptococcus, Turicibacter, and Bryantella. Of these, the most abundant were Lactobacillus, Bryantella, Bifidobacterium, and Turicibacter.

The physiology of bacterial species within a genus can vary. Thus, species differences within each genus between the two rat genotypes were considered an important component of these analyses. At the 1% level of confidence, 24 bacterial species differed in abundance between the two rat genotypes (Table 2). Among them, 11 were more abundant in BB-DR and 13 were more abundant in BB-DP. Some of these differences were within a genus that did not differ between the two rat genotypes. For example, although the number of reads of Clostridium did not differ between the two treatments, 6 species of Clostridium did differ. Of these, 5 were more abundant in BB-DP while one species was more abundant in BB-DR (Table 2).

At the genus level, Bacteroides strains were more prevalent in BB-DP rats than in BB-DR. However, at the species level, strains of B. capillosus, B. vulgatus and B. splanchnicus were more common in BB-DP while B. acidifaciens and B. massiliensis strains were more common in BB-DR. Four Lactobacillus species were more common in BB-DR samples but unidentified Glade, L. sp., was more common in BB-DP.

Example 5—Verification of the Pyrosequencing Results—Quantification of Lactobacillus and Bifidobacterium in the Diabetes-Prone and Diabetes-Resistant Samples

In an attempt to verify the accuracy of the results obtained by using pyrosequencing, quantitative PCR was performed to quantify the abundance of two bacterial genera (Lactobacillus and Bifidobacterium) that are more common in BB-DR than in BB-DP samples. The Ct values obtained were converted into cell number and the averaged number of bacterial cells for the BB-DR and BB-DP samples (FIG. 4). Both genera were more common in BB-DR than in BB-DP samples confirming the pyrosequencing results.

The expression of bacterial abundance in qPCR experiments as cell numbers is well documented and accepted in the literature (Byun et al. 2004; Martin et al., 2006). In addition, an excellent correlation has been shown between L. sakei counts estimated by real-time PCR and L. sakei counts on MRS plates (FIG. 2, Table 3, Martin et al. 2004). In this report we used the same approach. Briefly, the conversion to cell numbers is based on a calibration curve in which a small fragment from the 16S rRNA gene specific to Lactobacillus or to Bifidobacterium is amplified. To this end, chromosomal DNA from either Lactobacillus reuteri (wild type isolate) or Bifidobacterium sp (wild type isolate) were quantified and serial dilutions were made. Different concentrations from 50 fg to 5 ng (20 to 2×10⁶ genome equivalents) were used as a standard curve in the qPCR experiments.

Example 6—A Large Number of Sequences not Classified to the Genus Level

Most of the pyrosequences obtained could not be classified at the genus or species levels. Of those, 252 OTUs differed significantly between BB-DP and BB-DR. Of those, 139 were significantly more abundant in BB-DR while 113 where significantly higher in BB-DP. These organisms represented 24.4% and 21.4% of all reads in BB-DP and BB-DR, respectively. Of the 252 OTUs, 245 could be classified into five bacterial families: Clostridiaceae, Lachnospiraceae, Ruminococcaceae, Porphyromonadaceae, and Prevotellaceae (FIG. 5, Table 3). Of the 41 OTUs that differed between the two rat genotypes in the Clostridiaceae, 95% were more abundant in BB-DP than BB-DR. A similar trend was found in the Ruminococcaceae, where 67.9% of the 56 OTUs were more abundant in BB-DP than BB-DR. Conversely, of the 119 OTUs that differed between the two rat genotypes in the Lachnospiraceae, 77% were more abundant in BB-DR than BB-DP. The OTUs from Porphyromonadaceae and Prevotellaceae were also more likely to be in higher numbers in BB-DR than BB-DP.

TABLE 1 List of bacterial genera whose abundances differ statistically at the 1% level of confidence between the diabetes-resistant (BB-DR) and diabetes-prone (BB-DP) stool samples. The percent of total reads is shown for each genus. The percent of reads numbers in bold indicate the genotype (BB-DP or BB-DR), which is higher for that genus. Here a 16S rRNA sequence is considered to be derived from a known genus if it is at a similarity level of 95% or above to its closest cultured relative. Approximate genus level - 95% similarity to closest % of all % of all Fold cultured_relative Phyla BB-DP reads BB-DR reads p-value difference Bacteroides Bacteroidetes 6.732 6.101 2.00E−05 1.5 Bifidobacterium Actinobacteria 0.041 0.940 2.00E−05 16.8 Eubacterium Firmicutes 4.009 2.050 2.00E−05 2.6 Halothermothrix Firmicutes 0.126 0.003 2.00E−05 55.0 Lactobacillus Firmicutes 5.320 8.012 2.00E−05 1.1 Prevotella Bacteroidetes 0.307 0.630 2.00E−05 1.5 Pseudobutyrivibrio Firmicutes 0.112 0.453 2.00E−05 3.0 Ruminococcus Firmicutes 2.302 1.675 2.00E−05 1.9 Spiroplasma Mollicutes 0.000 0.112 2.00E−05 36 Anaerostipes Firmicutes 0.127 0.0523 0.000680 3.2 Mucispirillum Deferribacteres 0.224 0.130 0.000760 2.3 Butyrivibrio Firmicutes 0.030 0.000 0.000980 13 Proteiniphilum Bacteroidetes 0.062 0.143 0.001420 1.7 Streptococcus Firmicutes 0.025 0.081 0.001700 2.4 Turicibacter Firmicutes 0.654 0.909 0.002040 1.2 Pediococcus Firmicutes 0.032 0.003 0.003080 14 Sporobacter Firmicutes 1.396 1.262 0.007040 1.5 Bryantella Firmicutes 0.838 1.089 0.009580 1.4 Total of % reads 22.334 23.645

TABLE 2 List of bacterial species whose abundance differs statistically at the 1% level of confidence between the diabetes-resistant (BB-DR) and diabetes-prone (BB-DP) stool samples. The percent of total reads obtained from BB-DP or BB-DR is shown for each species. The percent of reads numbers in bold indicate the genotype (BB-DP or BB-DR), which is higher for that genus. Here a 16S rRNA sequence is considered to be derived from a known species if it is at a similarity level of 97% or above to its closest cultured relative. Approximate species level - 97% similarity to closest % BB-DP % BB-DR cultured relative Phyla reads reads p-value Bacteroides acidifaciens Bacteroidetes 0.119 0.437 2.00E−05 Bacteroides capillosus Bacteroidetes 2.213 1.014 2.00E−05 Bifidobacterium saeculare Actinobacteria 0.005 0.304 2.00E−05 Clostridium aldrichii Firmicutes 0.126 0.034 2.00E−05 Clostridium fimetarium Firmicutes 0.350 0.164 2.00E−05 Clostridium nexile Firmicutes 0.320 0.199 2.00E−05 Eubacterium siraeum Firmicutes 0.547 0.300 2.00E−05 Eubacterium ventriosum Firmicutes 0.430 0.096 2.00E−05 Lactobacillus frumenti Firmicutes 0.000 0.065 2.00E−05 Lactobacillus intestinalis Firmicutes 0.597 1.967 2.00E−05 Lactobacillus johnsonii Firmicutes 0.304 1.939 2.00E−05 Prevotella marshii Bacteroidetes 0.229 0.493 2.00E−05 Ruminococcus flavefaciens Firmicutes 0.339 0.158 2.00E−05 Spiroplasma helicoides Mollicutes 0.000 0.111 2.00E−05 Bacteroides vulgatus Bacteroidetes 0.492 0.338 6.00E−05 Lactobacillus sp. Firmicutes 0.959 0.810 0.000120 Mucispirillum schaedleri Deferribacteres 0.201 0.115 0.000400 Bacteroides splanchnicus Bacteroidetes 0.030 0.000 0.001260 Clostridium orbiscindens Firmicutes 0.222 0.143 0.001260 Bacteroides massiliensis Bacteroidetes 0.135 0.258 0.002280 Clostridium hylemonae Firmicutes 0.000 0.022 0.003660 Clostridium glycolicum Firmicutes 1.558 1.511 0.005760 Streptococcus oligofermentans Firmicutes 0.021 0.065 0.008820 Lactobacillus acidifarinae Firmicutes 0.000 0.019 0.009160 % of total reads 9.1970 10.562

TABLE 3 A large number of OTUs (252) differed significantly between BB-DR and BB-DP but could not be classified at the genus or species levels. The distribution of most (245) of these OTUs among five bacterial families is shown below. no. in no. in % % Family BB-DP BB-DR Total BB-DP BB-DR Clostridiaceae 39 2 41 0.951 0.049 Lachnospiraceae 27 92 119 0.227 0.773 Ruminococcaceae 38 18 56 0.679 0.321 Porphyromonadaceae 5 13 18 0.278 0.722 Prevotellaceae 0 11 11 0.000 1.000 Total 109 136 245 0.445 0.555

TABLE 4 Number of pyrosequencing reads obtained from each sample and the number of operational taxonomic units (OTUs) observed in each sample at the 97% and 95% level of similarity. No. of OTUs observed Reads/OTU pyrosequencing Level of similarity Sample reads 95% 97% 95% 97% Diabetes Prone BB-DP-1 6,178 654 962 9.45 6.42 BB-DP-2 7,101 714 1,059 9.95 6.71 BB-DP-3 6,321 558 793 11.33 7.97 BB-DP-4 4,573 475 702 9.63 6.51 BB-DP-5 3,961 513 750 7.72 5.28 BB-DP-6 3,936 457 661 8.61 5.95 BB-DP-7 2,812 411 607 6.84 4.63 BB-DP-8 1,265 296 417 4.27 3.03 BB-DP-9 1,261 223 327 5.65 3.86 BB-DP-10 7,997 825 1,210 9.69 6.61 Mean BB-DP 4,541 512.6 748.8 8.86 6.06 Diabetes Resistant BB-DR-1 2,750 413 557 6.66 4.94 BB-DR-2 7,712 1,100 1,689 7.01 4.57 BB-DR-3 3,574 525 804 6.81 4.45 BB-DR-4 3,764 637 967 5.91 3.89 BB-DR-5 2,704 541 794 5.00 3.41 BB-DR-6 3,392 495 723 6.85 4.69 BB-DR-7 2,020 385 539 5.25 3.75 BB-DR-8 3,178 274 427 11.60 7.44 BB-DR-9 1,968 317 477 6.21 4.13 BB-DR-10 2,750 172 270 15.99 10.19 Mean BB-DR 3,381 485.9 724.7 8.36 5.14

TABLE 5 List of bacterial genera whose abundances does not differ statistically at the 1% level of confidence between the diabetes-resistant (BB-DR) and diabetes- prone (BB-DP) stool samples. The percent of total reads is shown for each genus. The percent of reads numbers in bold indicate the genotype (BB-DP or BB-DR), which is higher for that genus. Here a 16S rRNA sequence is considered to be derived from a known genus if the 16S rRNA gene was at a similarity level of 95% or above to its closest cultured relative. Approximate genus level - % of all % of all 95% similarity to closest BB-DP BB-DR cultured relative Phyla reads reads p-value Rikenella Bacteroidetes 0.002 0.022 0.025319 Alistipes Bacteroidetes 1.249 1.523 0.036159 Shuttleworthia Firmicutes 0.007 0.028 0.039739 Paralactobacillus Firmicutes 0.000 0.009 0.083698 Methylobacterium Alphaproteobacteria 0.000 0.009 0.084358 Bulleidia Firmicutes 0.000 0.009 0.087498 Catonella Firmicutes 0.515 0.468 0.118618 Lachnobacterium Firmicutes 0.005 0.019 0.151877 Paenibacillus Firmicutes 0.000 0.006 0.193896 Leptotrichia Fusobacteria 0.000 0.006 0.194076 Hyphomonas Alphaproteobacteria 0.000 0.006 0.194816 Anaerofilum Firmicutes 0.000 0.006 0.194836 Escherichia Gammaproteobacteria 0.007 0.000 0.264014 Papillibacter Firmicutes 0.124 0.102 0.278874 Helicobacter Epsilonproteobacteria 0.041 0.028 0.333493 Porphyromonas Bacteroidetes 0.018 0.031 0.351713 Rothia Actinobacteria 0.005 0.012 0.414772 Anaerotruncus Firmicutes 0.005 0.012 0.417852 Desulfonispora Firmicutes 0.000 0.003 0.439011 Riemerella Bacteroidetes 0.000 0.003 0.439971 Tepidimicrobium Firmicutes 0.000 0.003 0.440071 Acinetobacter Gammaproteobacteria 0.000 0.003 0.441492 Syntrophococcus Firmicutes 0.000 0.003 0.443031 Slackia Actinobacteria 0.000 0.003 0.445231 Parabacteroides Bacteroidetes 0.174 0.211 0.500210 Parvimonas Firmicutes 0.005 0.000 0.504450 Sporotomaculum Firmicutes 0.005 0.000 0.507070 Anaeroplasma Mollicutes 0.005 0.000 0.507710 Dysgonomonas Bacteroidetes 0.352 0.409 0.510250 Thermobrachium Firmicutes 0.005 0.000 0.510950 Acetitomaculum Firmicutes 0.011 0.019 0.553909 Desulfotomaculum Firmicutes 0.076 0.068 0.587288 Peptostreptococcus Firmicutes 0.002 0.006 0.588528 Seinonella Firmicutes 0.215 0.251 0.595608 Acetanaerobacterium Firmicutes 0.007 0.003 0.634067 Hespellia Firmicutes 0.048 0.062 0.635547 Paludibacter Bacteroidetes 0.007 0.003 0.635727 Hallella Bacteroidetes 0.009 0.006 0.698786 Clostridium Firmicutes 8.901 9.616 0.732365 Anaerovorax Firmicutes 0.032 0.037 0.843783 Anaerofustis Firmicutes 0.002 0.000 1 Bacillus Firmicutes 0.007 0.006 1 Corynebacterium Actinobacteria 0.002 0.000 1 Dyella Gammaproteobacteria 0.002 0.000 1 Enterococcus Firmicutes 0.002 0.003 1 Ethanoligenens Firmicutes 0.002 0.000 1 Faecalibacterium Firmicutes 0.025 0.025 1 Gracilibacillus Firmicutes 0.005 0.003 1 Mahella Firmicutes 0.002 0.000 1 Megasphaera Firmicutes 0.002 0.000 1 Oscillatoria Cyanobacteria 0.002 0.000 1 Parasporobacterium Firmicutes 0.005 0.003 1 Rhodothermus Bacteroidetes 0.002 0.000 1 Roseburia Firmicutes 0.007 0.009 1 Sporobacterium Firmicutes 0.002 0.000 1 Tannerella Bacteroidetes 0.158 0.171 1 Total of % reads 12.059 13.229

TABLE 6 List of bacterial species whose abundance do not differ statistically at the 1% level of confidence between the diabetes-resistant (BB-DR) and diabetes- prone (BB-DP) stool samples. The percent of total reads is shown for each genus. The percent of reads numbers in bold indicate the genotype (BB-DP or BB-DR), which is higher for that genus. Here a 16S rRNA sequence is considered to be derived from a known species if the 16S rRNA gene was at a similarity level of 97% or above to its closest cultured relative. Approximate species level - % of all % of all 97% similarity to closest BB-DP BB-DR cultured relative Phyla reads reads p-value Turicibacter sanguinis Firmicutes 0.622 0.865 0.014120 Bacteroides dorei Bacteroidetes 0.245 0.382 0.015900 Pediococcus claussenii Firmicutes 0.016 0.000 0.016956 Ruminococcus callidus Firmicutes 0.085 0.047 0.017560 Bacteroides intestinalis Bacteroidetes 0.101 0.180 0.022112 Clostridium thermocellum Firmicutes 0.126 0.084 0.025819 Catonella morbi Firmicutes 0.002 0.021 0.027012 Lactobacillus pontis Firmicutes 0.650 0.611 0.044020 Clostridium herbivorans Firmicutes 0.016 0.047 0.050239 Clostridium disporicum Firmicutes 1.142 1.135 0.050478 Parabacteroides distasonis Bacteroidetes 0.119 0.084 0.052619 Pediococcus cellicola Firmicutes 0.016 0.003 0.079058 Ruminococcus schinkii Firmicutes 0.055 0.031 0.081138 Clostridium aerotolerans Firmicutes 0.030 0.012 0.089178 Bulleidia extructa Firmicutes 0.000 0.009 0.092158 Ruminococcus lactaris Firmicutes 0.000 0.009 0.093758 Paralactobacillus selangorensis Firmicutes 0.000 0.009 0.093858 Methylobacterium fujisawaense Alphaproteobacteria 0.000 0.009 0.093918 Clostridium sp. Firmicutes 0.025 0.009 0.105198 Eubacterium minutum Firmicutes 0.096 0.071 0.106438 Clostridium propionicum Firmicutes 0.032 0.016 0.110738 Bacteroides salyersiae Bacteroidetes 0.050 0.031 0.114318 Clostridium clostridioforme Firmicutes 0.014 0.003 0.135697 Ruminococcus luti Firmicutes 0.005 0.019 0.154297 Clostridium quinii Firmicutes 0.005 0.019 0.154897 Clostridium viride Firmicutes 0.016 0.037 0.165717 Lactobacillus kitasatonis Firmicutes 0.002 0.012 0.183456 Clostridium lentocellum Firmicutes 0.000 0.006 0.208096 Hyphomonas polymorpha Alphaproteobacteria 0.000 0.006 0.209956 Lactobacillus sobrius Firmicutes 0.011 0.003 0.234555 Lactobacillus reuteri Firmicutes 0.352 0.344 0.235635 Helicobacter bilis Epsilonproteobacteria 0.041 0.028 0.245095 Sporobacter termitidis Firmicutes 0.179 0.164 0.253875 Lactobacillus kalixensis Firmicutes 0.007 0.000 0.254275 Escherichia albertii Gammaproteobacteria 0.007 0.000 0.256735 Clostridium lituseburense Firmicutes 0.023 0.040 0.301434 Lactococcus garvieae Firmicutes 0.037 0.059 0.313754 Alistipes onderdonkii Bacteroidetes 0.002 0.009 0.335673 Bifidobacterium choerinum Actinobacteria 0.002 0.009 0.336193 Eubacterium eligens Firmicutes 0.002 0.009 0.336733 Clostridium stercorarium Firmicutes 0.034 0.056 0.378412 Rothia nasimurium Actinobacteria 0.005 0.012 0.420092 Anaerotruncus colihominis Firmicutes 0.005 0.012 0.422052 Acinetobacter johnsonii Gammaproteobacteria 0.000 0.003 0.453751 Eubacterium contortum Firmicutes 0.000 0.003 0.454011 Proteiniphilum acetatigenes Bacteroidetes 0.000 0.003 0.454591 Ruminococcus Firmicutes 0.000 0.003 0.455031 hydrogenotrophicus Lactobacillus homohiochii Firmicutes 0.000 0.003 0.455371 Ruminococcus obeum Firmicutes 0.000 0.003 0.455731 Alistipes shahii Bacteroidetes 0.000 0.003 0.455991 Riemerella anatipestifer Bacteroidetes 0.000 0.003 0.456411 Clostridium cylindrosporum Firmicutes 0.000 0.003 0.456711 Streptococcus pseudopneumoniae Firmicutes 0.000 0.003 0.457311 Slackia faecicanis Actinobacteria 0.000 0.003 0.457511 Bifidobacterium animalis Actinobacteria 0.007 0.016 0.479890 Eubacterium desmolans Firmicutes 0.007 0.016 0.484790 Papillibacter cinnamivorans Firmicutes 0.005 0.000 0.499350 Bacteroides plebeius Bacteroidetes 0.005 0.000 0.503410 Clostridium scindens Firmicutes 0.146 0.186 0.529709 Clostridium colinum Firmicutes 0.016 0.012 0.566689 Hespellia porcina Firmicutes 0.002 0.006 0.591848 Peptostreptococcus stomatis Firmicutes 0.002 0.006 0.595288 Alistipes putredinis Bacteroidetes 0.675 0.800 0.604808 Bacteroides eggerthii Bacteroidetes 0.039 0.053 0.610928 Clostridium irregulare Firmicutes 0.005 0.009 0.663227 Streptococcus pneumoniae Firmicutes 0.005 0.009 0.665327 Porphyromonas gingivalis Bacteroidetes 0.005 0.009 0.667327 Lactobacillus vaccinostercus Firmicutes 0.009 0.006 0.695426 Hallella seregens Bacteroidetes 0.009 0.006 0.696046 Bacteroides uniformis Bacteroidetes 0.009 0.006 0.696486 Eubacterium tenue Firmicutes 0.007 0.012 0.707766 Tannerella forsythensis Bacteroidetes 0.156 0.164 0.710786 Bryantella formatexigens Firmicutes 0.082 0.102 0.718446 Clostridium xylanolyticum Firmicutes 0.011 0.009 0.734845 Clostridium amygdalinum Firmicutes 0.140 0.149 0.773805 Clostridium alkalicellum Firmicutes 0.034 0.034 0.845623 Seinonella peptonophila Firmicutes 0.215 0.251 0.881002 Alistipes finegoldii Bacteroidetes 0.295 0.335 1 Clostridium algidixylanolyticum Firmicutes 0.002 0.000 1 Clostridium sporosphaeroides Firmicutes 0.005 0.006 1 Corynebacterium mastitidis Actinobacteria 0.002 0.000 1 Desulfotomaculum guttoideum Firmicutes 0.009 0.012 1 Dyella japonica Gammaproteobacteria 0.002 0.000 1 Enterococcus dispar Firmicutes 0.002 0.003 1 Eubacterium ruminantium Firmicutes 0.002 0.000 1 Gracilibacillus orientalis Firmicutes 0.005 0.003 1 Hespellia stercorisuis Firmicutes 0.002 0.003 1 Lactobacillus acidophilus Firmicutes 0.007 0.009 1 Lactobacillus catenaformis Firmicutes 0.002 0.000 1 Lactobacillus gastricus Firmicutes 0.002 0.000 1 Lactobacillus jensenii Firmicutes 0.002 0.000 1 Lactobacillus plantarum Firmicutes 0.002 0.000 1 Lactobacillus vaginalis Firmicutes 0.005 0.003 1 Mahella australiensis Firmicutes 0.002 0.000 1 Paludibacter propionicigenes Bacteroidetes 0.005 0.003 1 Prevotella baroniae Bacteroidetes 0.002 0.000 1 Prevotella bryantii Bacteroidetes 0.005 0.003 1 Rhodothermus marinus Bacteroidetes 0.002 0.000 1 Roseburia intestinalis Firmicutes 0.002 0.000 1 Shuttleworthia satelles Firmicutes 0.002 0.000 1 Total of % reads 6.135 6.796

Example 7—Determination of Lactobacillus Dosage in BB-DP Rats

An overly permeable gut has been found in BB rats and humans with type 1 diabetes. This physiological environment results in the translocation of normal flora or its metabolites to other organs. Considering this information was particularly relevant to determine the appropriate dosage of microorganisms for feeding experiments. The dosage of Lactobacillus can range from 10⁹ cells/animal for a mixed culture of Lactobacillus species to as low as 10⁴/animal for a pure culture of L. reuteri.

To determine the dosage of Lactobacillus strains capable of delaying or inhibiting the onset of type 1 diabetes, Lactobacillus strains isolated from diabetes-resistant rats (BB-DR) were administered to diabetes-prone rats (BB-DP). Briefly, a pilot experiment was performed by feeding L. johnsonii N6.2 or L. reuteri TD1 (strains isolated from BB-DR rats) to 1-day-old BB-DP rats during mother feeding for seven days to establish the optimal dosage of bacteria that can be administered to BB-DP rats without deleterious effects. The two lactic acid bacterial strains were administered individually (1×10⁶ or 1×10⁸ per animal per day) by oral gavage to 1-day-old BB-DP rats (N=5) during mother feeding for seven days. Colonies with different morphologies were isolated from either Rogosa (Lactobacillus selective media 14) or BHI plates (for anaerobes).

The results, as shown in FIG. 6, demonstrate that the administration of Lactobacillus prevents or significantly reduces bacteria translocation. In the control group (PBS fed), 60% of the animals had culturable bacteria in the spleen and liver (FIG. 6). The sequencing of the 16S RNA gene showed that different bacterial genera translocated to the spleen and liver in the control group. The genera found were: Paenibacillus, Bacillus, Escherichia, Lactococcus, and Lactobacillus. These data revealed that BB-DP rats exhibit greater intestinal permeability. In comparison, no translocation was observed in rats fed with 1×10⁶ L. reuteri TD1. In addition, only 20% translocation was observed in rats fed with L. reuteri TD1 at higher dosage (1×10⁸). This not only revealed that L. reuteri can be administered at either dose to the BB-DP rats, but more importantly, that the administration of L. reuteri TD1 can prevent bacterial translocation. A similar level of translocation was observed in rats fed with L. johnsonii N6.2 regardless of dose, albeit a lower level of bacteria translocation was observed in the control group.

Further, within the Lactobacillus fed groups, colonies isolated from the animals that showed bacterial translocation followed a similar distribution as found in the control group. This finding reveals that the feeding had a general protective effect rather than the targeted inhibition of a specific genus of bacteria.

Example 8—Decreased Incidence of Diabetes in BB-DP Rats Fed with L. Johnsonhii N6.2

To determine the ability of Lactobacillus strains for delaying or inhibiting the onset of type 1 diabetes, Lactobacillus strains isolated from diabetes-resistant rats (BB-DR) were administered to diabetes-prone rats (BB-DP).

Briefly, L. reuteri TD1 or L. johnsonii N6.2 suspensions (1×10⁸ CFU per animal) were administered i) pre-weaning to 1-day-old BB-DP rats during mother feeding; and ii) post-weaning to 21-day-old BB-DP rats (FIG. 7). The results, as shown in FIGS. 8A-8B, demonstrated that post-weaning administration of L. johnsonii N6.2 can delay the onset of diabetes in a rat model for up to 20 weeks. The post-weaning administration of L. johnsonii N6.2 produced the most significant beneficial effects on decreasing the incidence of diabetes (FIG. 8, P<0.04).

Example 9—Administration of L. johnsonii N6.2. Modifies the Intestine Microbiota

The impact of L. johnsonii N6.2. feeding on the intestinal microbiota was determined. RT-qPCR experiments were performed to measure the concentration of Pseudomonas, Bacteroides, Staphylococcus, Bifidobacterium, Clostridium, Lactobacillus, and enterobacteria in either the ileac or colonic content. Main groups of microorganisms were cultured as the animals developed diabetes. The abundance of specific bacterial genera was also measured by RT-qPCR.

Analysis of the ileac mucosa, as shown in FIGS. 9A-9B, unveiled an increase in the Lactobacillus population in the healthy rats; while a higher concentration of enterobacteria were found in the diabetic rats (FIG. 9). In addition, no statistically significant differences were observed on the stool culturable bacterial fractions of Lactobacillus, Bacteroides, or in the total anaerobe counts. The lack of differences of the microbiota in the stool samples, coupled with the statistically significant differences of microbiota in the ileal mucosa, demonstrate that the administration of L. johnsonii N6.2 could decrease the passage of pro-inflammatory antigens into the intestinal mucosa.

Example 10—the Gene Expression of Tight Junction Proteins is Modified Upon L. johnsonii Administration

It has been found that before the onset of diabetes, BB rats exhibit lower levels of the major intercellular tight junction protein claudin-1 and greater intestinal permeability. The early increment in intestinal permeability in the BB-DP rats allow unregulated passage of environmental antigens, which could trigger autoimmune responses leading to type 1 diabetes.

To determine the effect of L. johnsonii N6.2 on intestinal integrity, macroscopic modifications in the mucosal architecture were examined on hematoxylin and eosin stained slides of distal small intestine.

The results, as shown in FIGS. 10A-10C, revealed that no morphological differences between the L. johnsonii fed group, control healthy, or diabetic animals were found in villus height or width or crypt depth (FIG. 10A). In addition, necrosis was not observed. Compared to diabetic animals, healthy animals had a significantly higher amount of goblet cells (FIG. 10B, p<0.05).

At the molecular level, the expression level of claudin-1 and occludin proteins involved in tight junction assembly and maintenance were also measured. The results showed that the feeding of L. johnsonii upregulated the expression of claudin-1 and decreased the expression of occludin. The beneficial effects of L. johnsonii could be due to an amelioration of the barrier dysfunction observed in this animal model. Specifically, BB-DP rats exhibited low levels of the sealing claudin-1 but high levels of occludin TJ-related transmembrane protein (FIG. 10C).

Example 11—Effects of L. johnsonii on Host Oxidative Stress Response

Reactive oxygen species (ROS) species are generated early during disease development. These ROS species negatively affect the normal function of tissue and organs in various ways, including the disruption of epithelial tight junctions, leading to malfunction and tissue necrosis.

The host response to oxidative stress is complex. Multiple pathways of detoxification of reactive oxygen species (ROS) are involved in response to oxidative stress, including superoxide dismutase 1 and 2 (Sod1, Sod2), catalase (Cat), glutathione reductase (GR), and glutathione peroxidase (Gpx1) pathways.

The levels of hexanoyl-lysine, which is a biomarker for oxidative stress, have been determined by ELISA on ileum mucosa and were variable among the animals tested. It has been found that hexanoyl-lysine levels were significantly higher (P<0.05) in diabetic animals (53±21 μM·min-1) when compared to healthy animals (14±10 μM·min−1).

To further determine specific mechanisms involved, the mRNA levels of different enzymes involved in ROS detoxification pathways were measured. The results, as shown in FIG. 11A, revealed that all of the genes measured, except Sod1, were induced in the diabetic animals (FIG. 11A); whereas Sod1 expression was not modified under any condition.

Specifically, the expression of Sod2 and Gpx1 was induced in the diabetic animals (˜4.5 folds and ˜4 folds, respectively; P<0.05) and to a lesser extent Cat and GR (˜2 and 1.8 folds, respectively). By comparing the mRNA levels within the healthy animals (healthy controls vs. L. johnsonii fed group), it is determined that Cat and GR induction is correlated with the diabetic status of the animal. Gpx1 showed a higher response in the L. johnsonii fed group compared to healthy controls; while Sod2 was repressed only in the L. johnsonii fed group. In addition, the expression of Cox2 was repressed in diabetic animals (FIG. 11A, P<0.001), as compared to the L. johnsonii fed group.ROS also leads to the synthesis of nitric oxide by inducing nitric oxide synthase (iNOS). Nitric Oxide is a signaling molecule involved in the immune response against pathogens as well as early stages of many autoimmune diseases. The results, as shown in FIG. 11A, revealed that the mRNA levels of iNOS were significantly repressed in the L. johnsonii fed group, when compared to diabetic animals (˜22 fold, FIG. 11A, P<0.0001). Although no differences were observed between the control groups (healthy and diabetic), western blot analysis showed that iNOS expression is reduced in fed and control healthy groups (FIG. 11B), indicating that low levels of iNOS are correlated with the healthy status of the animals.

Example 12—Effects of L. johnsonii on TNFα and IFNγ Expression

iNOS modulates transcription and catalytic activity of cyclooxygenase 2 (Cox-2), which is directly linked to the prostaglandin production pathway. It is determined that mRNA levels of Cox2 were repressed 4 folds in diabetic BB rats. Similar repressive effect was observed in the levels of prostaglandin D synthase; while such repressive effect was reverted when insulin was administered. In addition, IFNγ, an important mediator of inflammatory responses with pleiotropic effects in the host, induces the expression of iNOS while represses the expression of Cox2.

Thus, this Example examined whether there is a negative correlation between the levels of various molecules, including IFNγ and other pro-inflammatory cytokines like TNFα, and L. johnsonii-mediated decrease in oxidative stress response in the host. The results, as shown in FIG. 12, revealed that mRNA levels of TNFα differ in ˜7 folds (P<0.05) between the healthy and diabetic animals; however, no differences in TNFα were observed within the healthy animals (FIG. 12). The results indicate that the modification in TNFα is correlated with the healthy status and not with the administration of the probiotic bacteria.

The expression of IFNγ, on the contrary, was related to the administration of L. johnsonii N6.2. In the diabetic animals, a ˜20-fold higher expression (P<0.005) of IFNγ was observed, as compared to the L. johnsonii N6.2 fed group. The lack of significant differences between the healthy controls and diabetic animals indicated that probiotic microorganisms contribute to the decrement of the inflammatory responses.

Example 13—the Effect of L. johnsonii on Indoleamine 2,3-Dioxygenase Expression (IDO)

Indoleamine 2,3-Dioxygenase expression (IDO) is an enzyme expressed at high levels in the small intestine and has been implicated in the regulation of intestinal inflammation. In NOD mice, IDO is a protective regulator of autoimmune responses. IDO mRNA levels in ileal mucosa follow a similar pattern of expression as shown for IFNγ (FIG. 12), a known inducer of IDO.

As shown in FIG. 13, L. johnsonii N6.2 fed animals had a 12-fold higher level of IDO expression, as compared to diabetic animals (FIG. 13); while a 4-fold lower expression in healthy animals was observed. These data revealed that IDO could act as a down regulator of the B cell homeostatic responses to commensal microbiota.

All patents, patent applications, provisional applications, and publications referred to or cited herein are incorporated by reference in their entirety, including all figures and tables, to the extent they are not inconsistent with the explicit teachings of this specification.

It should be understood that the examples and embodiments described herein are for illustrative purposes only and that various modifications or changes in light thereof will be suggested to persons skilled in the art and are to be included within the spirit and purview of this application.

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1-15. (canceled)
 16. A composition comprising L. johnsonii N6.2 bacteria and at least one antioxidant.
 17. The composition of claim 16, wherein the antioxidant comprises vitamin E, vitamin C selenium, glutathione, carotene or ubiquinone, or any combination thereof.
 18. The composition of claim 16, wherein the L. johnsonii N6.2 bacteria are dehydrated.
 19. A composition comprising a combination of L. johnsonii N6.2 bacteria and at least one of milk, yogurt, curd, cheese, fermented milk; milk-based fermented products, ice-cream, or milk-based powders, or any combination thereof.
 20. A capsule comprising an effective amount of L. johnsonii N6.2 bacteria, wherein the capsule protects the bacteria in the gastrointestinal tract for transport to the intestine.
 21. The capsule of claim 20, wherein the L. johnsonii N6.2 bacteria is dehydrated.
 22. The capsule of claim 20, wherein the capsule further comprises at least one antioxidant.
 23. The capsule of claim 22, wherein the at least one antioxidant comprises vitamin E, vitamin C selenium, glutathione, carotene or ubiquinone, or any combination thereof. 